RELATIONSHIP OF SALINITY AND DEPTH TO THE WATER TABLE ON Tamarix spp. (SALTCEDAR) GROWTH AND WATER USE A Thesis by KURTISS MICHAEL SCHMIDT Submitted to the Office of Graduate Studies of Texas A&M University in partial fulfillment of the requirements for the degree of MASTER OF SCIENCE December 2003 Major Subject: Rangeland Ecology and Management
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RELATIONSHIP OF SALINITY AND DEPTH TO THE WATER TABLE ON
Tamarix spp. (SALTCEDAR) GROWTH AND WATER USE
A Thesis
by
KURTISS MICHAEL SCHMIDT
Submitted to the Office of Graduate Studies of Texas A&M University
in partial fulfillment of the requirements for the degree of
MASTER OF SCIENCE
December 2003
Major Subject: Rangeland Ecology and Management
RELATIONSHIP OF SALINITY AND DEPTH TO THE WATER TABLE ON
Tamarix spp. (SALTCEDAR) GROWTH AND WATER USE
A Thesis
by
KURTISS MICHAEL SCHMIDT
Submitted to Texas A&M University in partial fulfillment of the requirements
for the degree of
MASTER OF SCIENCE
Approved as to style and content by:
Larry D. White
(Chair of Committee)
Ronald E. Sosebee
(Member)
Steven G. Whisenant (Head of Department)
James R. Kiniry
(Member)
Robert W. Knight (Member)
December 2003
Major Subject: Rangeland Ecology and Management
iii
ABSTRACT
Relationship of Salinity and Depth to the Water Table on Tamarix spp. (saltcedar)
Growth and Water Use
(December 2003)
Kurtiss Michael Schmidt, B.S., Texas A&M University
Chair of Advisory Committee: Dr. Larry D. White
Saltcedar is an invasive shrub that has moved into western United States riparian
areas and is continuing to spread. Saltcedar is a phreatophyte that can utilize a saturated
water table for moisture once established and is also highly tolerant of saline soil and
water conditions. Literature has indicated that depth to the water table and salinity has a
significant effect on growth and water use by saltcedar. Several studies were initiated to
help develop a simulation model of saltcedar growth and water use based on the
EPIC9200 simulation model. A study was initiated at the USDA-ARS Blackland
Research Center Temple, Texas in the summer of 2002 to better understand the effects
of water table depth and salinity on (1) saltcedar above and below ground biomass, root
distribution, leaf area and (2) water use. Five different salinity levels (ranging from 0
ppm to 7500 ppm) and three different water table depths (0.5m, 1.0m, and 1.75m) were
studied.
Results indicated that increasing depth to the water table decreased saltcedar water use
and growth. For the 0.5m water table depth, saltcedar water use during the 2002 growing
season averaged 92.7 ml d-1 while the 1.75m depth averaged 56.6 ml d-1. Both root and
iv
shoot growth were depressed by increasing water table depth. Salinity had no effect on
saltcedar growth or water use except, at the 1250 ppm level, which used 110 ml of H2O
d-1. This salinity had the highest water use indicating that this may be near the ecological
optimum level of salinity for saltcedar. A predictive equation was developed for
saltcedar water use using climatic data for that day, the previous days climatic data,
water table depth and salinity that included: previous day total amount of solar radiation,
water table depth, previous day average wind speed, salinity, previous day total
precipitation, previous day average vapor pressure, minimum relative humidity, previous
day average wind direction, and maximum air temperature. Data from the field study
and a potential growth study were integrated into the model. The model was
parameterized for the Pecos River near Mentone, Texas. Predicted saltcedar water use
was slightly lower than results reported by White et al. 2003.
v
DEDICATION
This thesis is dedicated to all my friends and family. Without their love, patience,
and help, I would not have ever completed this research.
iii
ACKNOWLEDGMENTS
First, I would like to thank Dr. Larry D. White for his help and guidance
with this project. Without his advice, ideas, encouragement, and help I would have
not completed this project.
I would like to thank Dr. James Kiniry, Dr. Ron Sosebee, and Dr. Bob
Knight for serving on my committee, help with the research and preparation of this
thesis, advice and support.
I would like to thank all the USDA-ARS staff including Dr. Jack DeLoach,
Deborah Spaniel, James Tracy, Thomas Robins, Henry Lyod, Martin Lopez, and
Jimmy Williams (TAES) for all there help, support and advice throughout my time
in and away from Temple.
I would also like to thank Tracy Gwaltney, Nikki Dictson, Christie Rivett,
B.J. Hill, and Dr. Larry D. White for freezing their fingers while we washed root
samples. Without there help I may have gone insane by the time I was done.
A special thanks to Tracy Gwaltney for reminding me about the details
since I rarely worried about them and to Theresa Swihart for listening to my
complaints and letting me vent.
iv
TABLE OF CONTENTS
Page ABSTRACT ................................................................................................................iii DEDICATION ............................................................................................................. v ACKNOWLEDGMENTS ..........................................................................................iii TABLE OF CONTENTS............................................................................................ iv LIST OF TABLE ........................................................................................................ vi LIST OF FIGURES ..................................................................................................viii INTRODUCTION ....................................................................................................... 1 OBJECTIVES.............................................................................................................. 3
Characterization of Naturally Established Stands ....................................................... 3 Characterization of Artificially Established Stands..................................................... 3 Model Development and Testing................................................................................ 3 Depth and Salinity ..................................................................................................... 3
LITERATURE REVIEW............................................................................................ 2
Saltcedar (Tamarix spp.) ............................................................................................ 2 Salinity Effects on Tamarix spp. ................................................................................ 2 Water Table Depth Effects on Saltcedar ..................................................................... 5 Transpiration and Evapotranspiration......................................................................... 8
Simulation Model .................................................................................................... 13 Characterization of Naturally Established Stands.................................................. 14 Characterization of Artificially Established Stands ............................................... 15 Saltcedar Simulation Model Development............................................................ 15 Model Testing ...................................................................................................... 17
Effect of Salinity and Water Table Depth on Saltcedar Growth and Water Use ........ 18 Cutting Establishment .......................................................................................... 18 Development of Experimental Unit ...................................................................... 18 Physical Facilities................................................................................................. 19 Salinity Treatment ................................................................................................ 19 Depth to Water Table ........................................................................................... 19 Sampling Procedure ............................................................................................. 21
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Data Collection .................................................................................................... 21 Statistical Analysis................................................................................................... 26
Characterization of Naturally Established Stands ..................................................... 28 Characterization of Artificially Established Stands................................................... 29 Effect of Salinity and Water Table Depth on Saltcedar Growth and Water Use ........ 30
Water Use ............................................................................................................ 30 Biomass ............................................................................................................... 35
Saltcedar Simulation Model Testing......................................................................... 43 Water Use by Saltcedar for the Pecos, Colorado, and Canadian Rivers
(Reported by Kiniry et al. 2003) ........................................................................... 43 Saltcedar Simulation Model Sensitivity ................................................................ 45
DISCUSSION and CONCLUSIONS ........................................................................ 65
Characterization of Naturally and Artificially Established Stands............................. 65 Effect of Salinity and Water Table Depth on Saltcedar Growth and Water Use ........ 66 Saltcedar Simulation Model Testing......................................................................... 73 Overall Conclusions................................................................................................. 75 Recommendations.................................................................................................... 75
Salinity and Water Table Depth Experiment ......................................................... 75 Saltcedar Simulation Model Development............................................................ 76
Page Table 1. Water use by saltcedar decreased as depth to the water table
increased. Modified from van Hylckama (1970). ......................................8 Table 2. Average leaf area index, light extinction coefficient, and age of small
saltcedar trees from sites in Texas, New Mexico and Colorado...............28 Table 3. Means of the ratio of saltcedar leaf area to fresh weight (cm2 g-1)
from five sites.........................................................................................29 Table 4. Average leaf area index (LAI) and light extinction coefficients (k) of
Tamarix spp. from Seymour, Texas, Tamarix ramosissima, Salix spp., and Populus spp. ............................................................................30
Table 5. Average minimum and maximum hourly rates of recharge of the soil
profile (water use) per day and time of occurrence with filtered observations across salinities. .................................................................31
Table 6. Time of peak and minimum recharge (water use), and average
minimum and maximum recharge (water use) rates. ...............................31 Table 7. Average daily recharge (water use by saltcedar) for each salinity and
water table level. ....................................................................................32 Table 8. Regression equation for recharge (water use by saltcedar) (ml d-1)
using the enter method with salinity and depth to the water table as the independent variables........................................................................33
Table 9. Regression equation for recharge (water use by saltcedar) (ml d-1)
using the stepwise method with salinity, depth to the water table and climatic data as the independent variables...............................................33
Table 10. Average recharge (water use by saltcedar) (ml/plant) across
salinities for the sight tubes.....................................................................34 Table 11. Average recharge (water use by saltcedar) (ml/plant) with
increasing water table depths for the sight tubes. ....................................35 Table 12. Average cutting sizes for each harvest date following establishment
of saltcedar in June 2002. .......................................................................36
vii
Table 13. Average amount of saltcedar roots in sections D and E for each harvest....................................................................................................37
Table 14. Average saltcedar stem weight, number and length for each harvest
date. .......................................................................................................37 Table 15. Average saltcedar biomass (g) for all harvest dates, salinities, and
water table depths. ..................................................................................38 Table 16. Average amount of saltcedar root biomass across all harvest dates
and salinities for each water table depth..................................................42 Table 17. Average saltcedar top growth across all harvest dates and salinities
for each water table depth.......................................................................43 Table 18. Mean annual and mean daily plant water use (transpiration) (mm) as
estimated by the saltcedar simulation EPIC model, for the Pecos River site with different saltcedar cover (LAI) and for the Colorado and Canadian sites with representative plant cover (Kiniry 2003). ..........44
Table 19. Summary of evapotranspiration studies on saltcedar. .............................82 Table 20. Summary of all model runs....................................................................87
viii
LIST OF FIGURES
Page Figure 1. Layout of experimental unit for water table depth and salinity study. .....20 Figure 2. Diagram of depth and salinity study equipment setup. ............................24 Figure 3. Photograph of lysimeter study, angle view showing rows of trees
before initiation of study......................................................................25 Figure 4. Photograph of lysimeter study, side view, showing different water
levels. ..................................................................................................25 Figure 5. Demonstration of root washing technique using a slanted board. ............26 Figure 6. Average saltcedar root biomass distribution (g) for water table
depths across all harvest dates and salinities. .......................................39 Figure 7. Average saltcedar root biomass distribution (g) for salinities across
all harvest dates and water table depths................................................40 Figure 8. Average saltcedar root biomass distribution (g) by water table depth
for each harvest date across all salinities. .............................................41 Figure 9. Effect of plant salt sensitivity factor and soil salinity on the saltcedar
simulation model’s predicted soil water evaporation. ...........................46 Figure 10. Effect of plant salt sensitivity factor and soil salinity on saltcedar
simulation model’s predicted plant transpiration. .................................47 Figure 11. Effect of plant salt sensitivity factor and soil salinity on saltcedar
simulation model’s predicted evapotranspiration..................................48 Figure 12. Effect of plant salt sensitivity factor and soil salinity on saltcedar
simulation model’s predicted potential evapotranspiration. ..................49 Figure 13. Effect of plant salt sensitivity factor and soil salinity on saltcedar
simulation model’s predicted biomass production. ...............................50 Figure 14. Effect of initial depth to the water table on the saltcedar simulation
model predicted biomass production. ...................................................51
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Figure 15. Effect of minimum depth to the water table on potential evapotranspiration using the saltcedar simulation model. .....................52
Figure 16. Effect of minimum depth to the water table on plant transpiration
using the saltcedar simulation model....................................................53 Figure 17. Effect of minimum depth to the water table on soil water
evaporation using the saltcedar simulation model. ...............................54 Figure 18. Effect of maximum depth to the water table on biomass production
using the saltcedar simulation model....................................................55 Figure 19. Effect of maximum depth to the water table on potential
evapotranspiration using the saltcedar simulation model. .....................56 Figure 20. Effect of maximum depth to the water table on soil water
evaporation using the saltcedar simulation model. ...............................57 Figure 21. Effect of maximum depth to the water table on plant transpiration
using the saltcedar simulation model....................................................58 Figure 22. Effect of potential leaf area index on potential evapotranspiration
using the saltcedar simulation model....................................................59 Figure 23. Effect of potential leaf area index on evapotranspiration using the
saltcedar simulation model...................................................................60 Figure 24. Effect of potential leaf area index on plant transpiration using the
saltcedar simulation model...................................................................61 Figure 25. Effect of potential leaf area index on soil water evaporation using
the saltcedar simulation model. ............................................................62 Figure 26. Effect of potential leaf area index on biomass production using the
saltcedar simulation model...................................................................63 Figure 27. Plot of the difference of PET minus ET (mm) versus potential leaf
area index using the saltcedar simulation model...................................64 Figure 28. Average water use of saltcedar using water loggers and sight tubes
for each salinity level across all water table depths. .............................67 Figure 29. Average water use of saltcedar using water loggers and sight tubes
for each water table depths across all salinities.....................................67
x
Figure 30 Regression equations for this study and other studies using water table depth to predict average annual saltcedar water use (cm yr-1).......69
Figure 31. Photograph of root distribution of saltcedar grown in an individual
Saltcedar (Tamarix spp.) was introduced to the United States from Asia and
southeastern Europe. It was first introduced into the US around the 1870’s as an
ornamental (Tesky 1992). Later widespread planting to control stream bank erosion
accelerated its establishment throughout the United States. There are thought to be
approximately 54 species of Tamarix spp. in the world (DeLoach and Lewis 2000). Of
these, ten have been introduced into the U.S. Out of these ten, three are widespread
with T. ramosissima and T. parviflora being major problem species while T. aphyllla is
not considered a problem species.
Saltcedar is an aggressive and invasive phreatophyte that can tolerate a wide
range of environmental conditions, producing large amounts of seed, propagating
vegetatively and withstanding high salinity. Saltcedar has been blamed for
displacement of native plant species, decreased wildlife habitat values, increased
salinity of surface soil, and excessive groundwater consumption (Carpenter 2000).
Saltcedar has some positive benefits such as habitat for nesting birds, ornamental and
shade trees, windbreaks, erosion stabilization, and for production of honey.
Saltcedar has a competitive advantage over many native plant species through
several mechanisms. DeLoach et al. (1997) identified nine factors that gives saltcedar
its competitive advantage: 1. Altered hydrologic cycle and flood levels: Shifting from
natural hydrologic cycles to ones induced by man through the building of dams and
reservoirs has shifted the competitive advantage from native species such as
cottonwood and willow to saltcedar. 2. Salinity: In areas with low rainfall or where
This thesis is written to conform to the style of the Journal of Range Management.
2
annual floods have been eliminated, saltcedar can raise the levels of salt in and on the
soil due to the exudates and high concentrations of salt in the leaves that fall to the soil
surface following leaf drop. This gives it a competitive advantage since the salt is not
leached and saltcedar can withstand higher levels of soil salinity than many native
species. 3. Fire: saltcedar is not killed by fire and quickly re-sprouts, unlike native
species such as cottonwood. 44.. Drought and low water tables: Saltcedar plants are
thought to be more tolerant of low moisture levels and declining water table rates than
many native species. This gives saltcedar an advantage during drought and falling water
tables. 5. Palatability to grazers: Saltcedar is not very palatable, unlike saplings of
native cottonwood and willow. This decreases native plant recruitment and puts natives
at a disadvantage. 6. Inundation: Saltcedar survives inundation longer during flooding
than most native species. 7. Transpiration:
Saltcedar has a specialized physiology that causes stomatal closure and results in transpiration rates considerably below potential during the hottest part of the day. This enables saltcedar to minimize transpirational losses relative to carbon gains by being more metabolically active in late morning rather than during the hottest part of the afternoon, as do most other plant species
8. Conventional controls: Most conventional control methods kill native vegetation
easier than saltcedar. After controls are applied, saltcedar resprouts while many native
species are killed. 9. Lack of natural controls: In its native range in Europe and Asia,
saltcedar has over 300 natural enemies. As an exotic plant in North America, it lacks
significant natural enemies while native species such as cottonwood and willow have
over 100 species of insects preying on them. Lack of natural insects gives saltcedar a
competitive advantage. These factors are especially important to saltcedar competing
along rivers where the hydrology has been changed.
3
OBJECTIVES
Several studies were initiated to develop and evaluate a growth and water use
model of saltcedar. The specific objectives of each study are listed below:
Characterization of Naturally Established Stands
1. Determine if there are significant correlations between age of plant, leaf area
index, and light extinction coefficient.
2. Determine if there are significant differences between collection sites.
Characterization of Artificially Established Stands
1. Determine potential leaf area index and light extinction coefficients for Tamarix
ramosissima from CA, Tamarix spp. from Seymour, Texas, Salix nigra, and
Populus deltoids from Temple, TX.
2. Determine if there are significant differences in leaf area index and light
extinction coefficients between species of trees.
Model Development and Testing
1. Advise on the development of a water use and growth model for saltcedar.
2. Evaluate the model using data from literature, depth and salinity study, and
ongoing water use studies on the Pecos, Colorado and Canadian rivers in Texas.
Depth and Salinity
1. Determine effects of salinity and water table depth on saltcedar water use and
growth.
2. Develop a multiple linear regression predictive equation for water use.
2
LITERATURE REVIEW
Saltcedar (Tamarix spp.)
Saltcedar (Tamarix spp.) was introduced into the United States from Asia and
southeastern Europe. It was first introduced around the 1870’s as an ornamental, but
since then was used for stream bank stabilization and has established itself throughout
the southwestern United States and Mexico (Tesky 1992). Approximately 54 species of
saltcedar are believed to exist in the world (DeLoach and Lewis 2000). Of these, ten
have been introduced into the U.S. Out of these ten, three are widespread with T.
ramosissima and T. parviflora being major problem species while T. aphyllla is not
considered a problem.
Salinity Effects on Tamarix spp.
As a soil becomes progressively more saline it becomes more difficult for a
plant to extract water from the soil/water profile. This is caused by lower osmotic
potential that increases the solution entropy and forms associations between water
molecules and the solute. This creates water stress in plants as solute content of the
soil/groundwater increases and the ability of the roots to take up water decreases
(Lambers et al. 1998). In order to survive in high saline environments, tolerant plants
have several mechanisms including exclusion, storage and excretion.
Plants can exclude salt from uptake through passive and active mechanisms.
Passive exclusion occurs through having high amounts of phospholipids in their
membranes, which restricts movement of chloride to the shoot while allowing uptake of
other ions (Lambers et al. 1998). A benefit of active uptake of salts would be lowering
3
the water potential of a plant. This would give the plant the ability to take up more
water as the water potential of the soil/groundwater decreases.
Salt tolerance and effects of increasing salinity are difficult to quantify because
they vary considerably with both environmental and plant factors (Kozlowski 1997).
Environmental factors could include soil fertility, soil physical conditions, distribution
of the salt in the soil profile, and climate. Plant factors that could influence a plant’s
reaction to salinity include stage of growth, variety, and individual plant genetics.
Saltcedar excretes salt by use of salt hairs (trichomes) or through the use of salt
glands (Lambers et al. 1998). Plants may employ this strategy when
compartmentalization of salt no longer becomes possible. This may occur when the
plant can no longer adequately store salts because of simple lack of space. Use of salt
hairs and glands are active processes and require energy, which reduces growth.
Saltcedar can exhibit both of these mechanisms and excrete salt so effectively that they
can acquire masses of salt on their leaves that are easily observed by the naked eye.
Excretion rates of NaCl are positively correlated with increasing concentrations of
NaCl (Hagemeyer and Waisel 1988). Excretion rates of Ca2+ are negatively correlated
with increasing levels of NaCl while excretion rates of K and Mg are not significantly
affected.
Around Utah Lake in Utah, saltcedar occurs on sites with soil salinities ranging
from 700 to 15,000 ppm (Carman and Brotherson 1982). Russian olive (Elaeagnus
angustifolia), another invasive phreatophyte, occurs on sites with lower salinities
ranging from 700 to 3,500 ppm. There is some evidence that significant decreases in
growth of saltcedar does not occur until salinity levels reach 36,000 ppm while native
4
Populus fremontii and Salix gooddingii cannot tolerate levels over 1,500 ppm (Jackson
et al. 1990). Saltcedar is so tolerant of salinity that Tomar et al. (2003) ranked it as the
number one genus when evaluated on the basis of survival, growth, and biomass yield
in order of performance and persistence under saline conditions when compared to 31
other tree species under irrigation. Foliar elemental analysis gives support for
classification of saltcedar as a halophyte when concentrations of elemental
concentrations were compared to native Populus spp. and Salix spp. on the Bill
Williams and Colorado rivers in Nevada (Busch et al. 1995).
Increasing levels of salinity decrease seedling germination, shoot growth, and
below ground growth of saltcedar (Tomanek and Ziegler 1962). Growth rates decrease
with increasing salinity levels (Kleinkopf and Wallace 1974, Jackson et al. 1990, Glen
et al. 1998). This decreased growth is due to energy cost associated with salt pumping,
increased respiration (Kleinkopf and Wallace 1974) and decreased photosynthetic rates
(Jackson et al. 1990). Tamarix jordansis has been reported to contain proline analogues
that can ameliorate the effects of increased NaCl levels on rubisco activity (Solomon et
al. 1994).
A couple of studies reported different findings. Stevens (1989) found a
significant increase in relative growth rates when seedlings of saltcedar where watered
daily in pots with a NaCl solution ranging in strength from 0 to 5,844 ppm. He found
no shift in root to total biomass ratios across salinities. Shafroth et al. (1995) found no
significant effects of increasing salinity on aboveground or belowground growth of
saltcedar in salinities up to five times the concentrations of major ions in the Rio
Grande at San Marcial, NM.
5
It has been reported in numerous studies that saltcedar water use is affected by
increasing salinity levels. As salinity levels increase transpiration decreases (Van
Hylckama 1963, Hagemeyer and Waisel 1987, Hagemeyer and Waisel 1989, and
Vandersale 2001).
Water Table Depth Effects on Saltcedar
Since saltcedar is considered a phreatophyte, under natural conditions it gets
most of its water from the water table. However, it has been shown that saltcedar is able
to utilize shallow soil moisture (Mounsif et al. 2002) when present. Robinson (1958)
described how water table depth affected growth and decreased evapotranspiration (ET)
of saltcedar. As water table depth increases saltcedar must send its roots down farther
to reach the capillary fringe where its fine root mass normally resides. Thus, water use
decreases with increasing water table depth.
Water tables can fluctuate considerably due to seasonal and annual changes in
inflows as well as fluvial processes (Shafroth et. al. 2000) and transpiration by riparian
vegetation. Plant roots tend to accumulate near the surface of the water table and can
be flooded or stranded by rapid fluctuations. A water table decline of 1.1 m from the
previous year level of 0.9 m resulted in 92-100% mortality of Populus and Salix
saplings, whereas, only 0-13% of saltcedar stems died. According to Shafroth et al.
(2000) riparian plant survival depends on the:
magnitude of groundwater decline relative to the pre-decline distribution of
roots, rate of decline, duration of decline, ability of the plant to grow new roots
to adjust water demand (e.g., via physiological and morphological adaptations),
plant age and size, transpirational demand, and importance of other sources of
6
water (e.g., precipitation) to the overall plant water supply………….Plant
response is likely mediated by other factors such as soil texture and stratigraphy,
availability of precipitation-derived soil moisture, physiological and
morphological adaptations to water stress, and tree age.
Gary (1963) found that saltcedar roots adapt to favorable soil moisture conditions. In
areas were the water table was deep, saltcedar produced long taproots and the branch
roots were vertical in nature. The branch roots occupied the areas immediately above
the groundwater table and were in the capillary fringe. He also found that when the
water table was high, saltcedar developed a taproot and secondary roots that occupied
all zones of the soil profile above the water table. Saltcedar roots have been observed at
depths as great as 30m (Robinson 1958).
Stromberg (1998) reported a positive linear correlation between stand age and
depth to the groundwater. This indicates groundwater decline may have been caused by
the saltcedar and that it is capable of following the declining water table. Busch et al.
(1992) found that saltcedar not only gets water from the water table, but also is capable
of getting it from unsaturated alluvial soils. This evidently gives saltcedar a competitive
advantage over native phreatophytes that are not able to survive when water levels are
low or non-existent. Horton and Clark (2001) conducted a greenhouse experiment on
seedlings in which water table decline altered growth and survival of saltcedar and
Salix seedlings. Salix seedling survival and growth was greatest with no decline and
survival and growth decreased as decline rates increased to 4.0 cm d-1. Saltcedar
seedling survival and growth was greatest with no decline and 1.0 cm-1 day decline
levels and had consistently higher survival and growth when compared to Salix spp.
7
across all treatment levels. Root elongation rates were greatest for saltcedar at the water
table decline rate of 1 cm/day. Busch et al. (1992) used isotopes to investigate the
source of water for woody phreatophytes on the Bill Williams and lower Colorado
Rivers in Arizona. Saltcedar used groundwater and non-saturated alluvial soils. This
suggests that saltcedar is a facultative phreatophyte that uses water when it is freely
available but “can do just fine” when a constant water supply is not available.
The distance from the water source and depth to the water table directly affects
water use. Devitt et al. (1997a,b) found that sap flow decreased in saltcedar as the water
table and soil water declined (lysimeters placed at desert edge, river edge and open
stand). They found that “daily sap flow totals on a leaf area basis were higher for the
plants growing along the river’s edge, with midday hourly values significantly higher
when a water table was present.” This study also had a dry down phase that showed
sap flow decreased in the river’s edge and open stand lysimeters as the water table
dropped. In large stands there can be considerable differences in water use by
individual plants across the riparian zone due to water availability and competition.
Horton et al (2001b,c) found there was a negative relationship between water table
depth and shoot water potential, stomatal conductance, and photosynthetic rate.
Saltcedar uses less water as water table depth increases (Gatewood et al 1950,
Van Hylckama 1970, Dahm et al 2002). Saltcedar grown in evapotranspirometers, in a
dense thicket in Arizona, used 2.26 m yr-1 with a depth to the water table of 1.5 m and
0.87 m yr-1 with a depth to the water table of 2.70 m (van Hylckama 1970) (Table 1).
He concluded that given a lower water table, saltcedar may thrive but uses considerably
less water.
8
Though several studies have indicated that water table has an effect on water
use, several studies showed no significant effect: Wilkinson (1972) found no significant
differences in relative water contents of one tree with a water table 0.9 m deep versus
trees with a water table of 3.1 m or more in lysimeters. He concluded that water table
depth was not a major contributive factor in the water supplies of these trees. Weeks et
al. (1987) found no correlation between water use and depth to the water table when
they used eddy covariance and energy budget methods. Plant densities and ages varied
substantially at all their sites and could have masked any effect water table depth might
have. Horton et al. (2001a) reported that shoot water potentials, leaf gas exchange rates,
and canopy dieback were significantly related to water table depth for native species,
but not Tamarix chinensis. This indicated that saltcedar is much more drought tolerant
than native species.
Transpiration and Evapotranspiration
Most estimates of saltcedar water use are estimates of evapotranspiration and
not transpiration. Estimates of evapotranspiration from saltcedar stands range from as
high as 421 cm yr-1 on the Canadian river in Texas to as little as 32 cm yr-1 on the
Colorado River (White et al 2003). This illustrates that ET is very site specific due to
differences in water table depth, salinity, and hydraulic conductivity of the water table,
Table 1. Water use by saltcedar decreased as depth to the water table increased. Modified from van Hylckama (1970).
Depth to Groundwater
Water Use m yr-1 1961
Water Use m yr-1 1962
Water Use m yr-1 1963
Average m yr-1 (STD)
1.50 m 1.99 2.18 2.26 2.14(0.139) 2.10 m 1.41 1.37 1.59 1.46(0.117) 2.70 m 1.05 0.94 0.87 0.95(0.091)
9
soil and solution. Transpiration by saltcedar has been estimated as low as 40 cm yr-1to
as high as 285 cm yr-1at Benardo, NM (Davenport et al 1982). See appendix B for
summary of reported ET and transpiration values for saltcedar. Variation in estimates of
ET can be due to not only the previously mentioned factors of water table depth and
salinity, but also due to vegetation/stand characteristics, atmospheric conditions and
method used to calculate water use (White et al 2003).
Saltcedar transpires in a diurnal rhythm usually peaking around noon (Gay and
Sammis 1977). Hagemeyer and Waisel (1987) found under continuous light in
laboratory conditions saltcedar exhibits an endogenous circadian rhythm (24 hour
cycle). This indicates that while environmental factors may influence transpiration,
saltcedar does have an internal “clock” regulating transpiration. Williams and Anderson
(1977) showed saltcedar to transpire at high rates until noon and then began a gradual
decrease that continued through out the afternoon. It was also shown that, the relative
water content (RWC) and water potential decreased sharply from sunup to 09:00 and
then remained constant or increased throughout the afternoon. When twigs were held at
constant temperature and relative humidity, a depression in transpiration occurred in the
afternoon, suggesting that saltcedar is controlled by a diurnal rhythm. Smith (1989)
found maximum water potential occurred at dawn for saltcedar and the minimum water
potential at noon. Peak stomatal conductance occurred around 10:00 and decreased
throughout the day when relative humidity was 22% and maximum air temperature was
26 C in April. By May peak stomatal conductance occurred at dawn and continued to
decrease throughout the day with a relative humidity of 8% and maximum air
temperature of 32 C. Transpiration in April peaked around noon and taper off as the
10
day progressed while in May transpiration peaked at 10:00. Mounsif et al. (2002)
found peak stomatal conductance of saltcedar to occur around 10:00 and peak
photosynthesis to occur between 10:00 and 12:00.
Using carbon isotope ratios to determine water use efficiency of several native
species and saltcedar on the Bill Williams and Colorado rivers in Arizona, Busch et al
(1995) found that saltcedar had a higher WUE than native phreatophytes, which gave it
a competitive advantage over native species when under water stress. Gay and Sammis
(1977) found saltcedar to transpire at rates ranging from 0.5 to 2.78 µg cm-2 s-1 (LAI
8.1) while mesquite, with a leaf area index (LAI) less than 3.0, was found to transpire at
1.2 to 11.2 µg cm-2 s-1. If projected onto a stand level, the much higher LAI of saltcedar
would compensate for the lower rate per unit of leaf area. Anderson (1977,1982) found
saltcedar to transpire at a rate of 1.2 g g-1 h-1 (mass of water per unit of leaf fresh mass
per hour) or 1.5 g dm-2 h-1 (mass of water per unit leaf area per hour) and 3.11 g g-1 h-1
(mass of water per unit of dry fresh mass per hour) at 30 C and 45% RH.
Stand density and LAI are important factors for saltcedar transpiration on an
area basis. Davenport et al. (1982) reported saltcedar water use in stands and drums. In
California during July for stands of saltcedar grown in drums, ET varied from 2.0 mm
day-1in a sparse stand up to 16.0 mm day-1in a dense stand. While greater stand density
had more total water transpired, the amount transpired per plant was greatest on the
sparse stand. Cleverly et al. (2002) measured ET using the 3-dimensional eddy
covariance method for a growing season at two sites on the Middle Rio Grande in New
Mexico, one site being flooded and the other nom-flooded. The unflooded site had a
low LAI of 2.5 and a mixture of plants including Tamarix ramosissima, Distichlis
11
spicata, Atriplex spp., Salix exigua, and Prosopis pubescens. The flooded site had a
higher LAI but, a monospecific stand of T. ramosissima. Total ET was 122 cm yr-1 for
the flooded site and 74 cm yr-1 for the non-flooded site. Smith et al (1995) found that
daily sap flow increased linearly with increasing leaf area. Dahm et al (2002) calculated
ET using the eddy covariance method on the Middle Rio Grande at several different
sites. LAI measurements were positively correlated with daily ET rates in this study.
Methods used to calculate water use can also show mixed results. Gay and
Fritchen (1979) estimated ET using the Bowen ratio and constant level lysimeters at
Benardo, NM for a 5-day period during hot and dry weather in June. The lysimeters
maintained a constant water depth of 1.5m. The Bowen ratio calculated mean ET was
8.2 mm day-1 while the lysimeters reported an average use of 7.99mm day-1. Weeks et
al. (1987) reported that over a range of sites with saltcedar, ET from the eddy
covariance method was consistently lower than the energy budget method. Gatewood
et al. (1950) used six different methods to calculate water use by bottomland vegetation
including the tank and transpiration well methods. The tank method was found to be
19% above the average of all 6 methods while the transpiration well method was 6%
below the average of all 6 methods. This indicates that there is a considerable degree of
disagreement between these two methods.
Calculated potential evapotranspiration (PET) can be an indicator of how much
water saltcedar is going to use but is not an absolute. Several studies have noted that ET
from saltcedar stands can exceed PET. Sala et al. (1996) conducted a study on
saltcedar, Pluchea, Prosopsis, and Salix using sap flow measurements to determine
estimates of transpiration. It was found that water use increased linearly when weighted
12
by PET with increasing leaf area. It was also found that dense (high leaf area) stands of
saltcedar are capable of transpiring 1.6-2.0 times the estimated PET. White et al. (2003)
attributed high ET estimates on the Canadian and Pecos Rivers in Texas to advective
energy affecting narrow bands of riparian vegetation. Smith et al (1998) conducted a
study on the lower Virgin River floodplain in Nevada investigating ET using the
Bowen ratio method and the effect of applied irrigation on saltcedar stomatal
conductance. ET exceeded PET early in the season when water tables were high and
soil was moist because of apparent advection from the surrounding desert. As the
summer progressed, ET fell below PET because of lack of soil moisture and water table
decline. An irrigation experiment was conducted to determine the effects of summer
rain on saltcedar stomatal conductance. Irrigation did not produce any increases of
stomatal conductance for at least 4 weeks suggesting that saltcedar does not readily
utilize summer rainfall events in the Mojave Desert.
13
METHODOLOGY
Simulation Model
The simulation model used was a modified version of EPIC 9200.Two studies
were conducted to help develop parameters for the growth and water use simulation
model for saltcedar. The first (natural stands) was to determine if there were any
significant correlations between age of plant, LAI, and light extinction coefficient and
determine if there were any significant differences between collection sites. The second
(artificially established stand) was to determine potential LAI and light extinction
coefficients for Tamarix ramosissima from California, Tamarix spp. from Seymour,
Texas, Salix nigra, and Populus deltoids from Temple, TX and to determine if there
were any significant differences in LAI and light extinction coefficients between these
species.
After appropriate parameters were developed, EPIC 9200 was set up by USDA-
ARS staff for sites being monitored by the Texas Cooperative Extension on the Pecos
River near Mentone, TX and runs made for, sites on the Colorado River near Snyder,
TX, and the Canadian River near Canadian, TX. Multiple runs for the Pecos River site
were conducted to test sensitivity of the model to changes in soil salinity, plant salt
sensitivity, minimum water table depth, maximum water table depth, and potential LAI.
The average response of PET, ET, plant transpiration, soil water evaporation, and
biomass were evaluated. Model estimates of ET were compared to those reported by
White et al. (2003) for the respective sites.
14
Characterization of Naturally Established Stands
Light interception, leaf area, ring counts, and aboveground biomass to
determine leaf area index, radiation use efficiencies, light extinction coefficients and
ages were collected in the summers of 2001 and 2002 from the following locations:
Lake Proctor, TX; Wichita River near Seymour, TX; Canadian River near Canadian,
TX; Colorado River in Borden County, TX; Rio Grande river Las Cruces, NM; and the
Pueblo Reservoir near Pueblo, CO. Small isolated trees were targeted for collection for
development of the simulation model. Light interception was measured using a
Decagon PAR light bar 0.8 m long. First one average reading was taken above the plant
then an average of readings was taken below the plant along the length of the shadow
then another average above light reading was recorded. Foliage was then stripped and
the same series of measurements were taken again. Light interception by leaves could
then be calculated. The foliage was saved to determine weight using a scale and leaf
area using a LI3100 leaf area meter (LiCor Inc., Nebraska, USA.) The rest of the plant
was then harvested to determine aboveground biomass. The trees were aged by
counting growth rings at ground level. After leaf area had been measured the foliage
was dried at 55° C and periodically weighed until weights stabilized and then recorded
as the dry biomass. Leaf area index was calculated by dividing the total leaf area of
each sample plant by the area occupied by the shadow of each plant: m2 of one-sided
leaf area/ m2 of area occupied by the sample plant’s shadow.
Light extinction coefficient was calculated by taking the natural log of one
minus the fraction of photosythetically active radiation (PAR) intercepted by the plant
and dividing by the LAI: (ln(1-Fraction of PAR intercepted))/ LAI.
15
Characterization of Artificially Established Stands
This study was initiated at the beginning of June 2001 at the Blackland
Research Center, Temple, Texas to determine light extinction coefficients and
characterize saltcedar, willow and cottonwood plants under constant irrigation during
the 2001 growing season.
Water lines were trenched at the beginning of the summer, one-inch lines were
laid in the trenches and 11 drip irrigator heads were installed to assure that water was
not a limiting factor. Each of the main lines in turn had a cutoff valve. Forty-eight holes
0.3 m in diameter approximately 0.8 m deep were dug with an auger. They were filled
with Pedernales fine sandy loam soil. Four species were planted: Tamarix ramosissima
from California, Tamarix spp. from Seymour, Texas on the Wichita River, and local
cottonwood and willow from Temple, TX. They were planted in 4 blocks, each block
containing all 4 species with each species occupying 3 holes. They were planted using
cuttings approx 0.3 m long and 1.3 cm in diameter. Approximately 5 cuttings were
placed in each hole to ensure establishment of viable plants. The cuttings were watered
continuously 4-5 days each week during the summer. During the fall of 2001, the plants
were thinned out in each hole, leaving one plant per hole so that growth could continue
without competition.
During the 2002 growing season plants were continuously watered under drip
irrigation throughout the growing season. During the fall of 2002, light interception was
measured for each plant using the same procedure as for the field samples.
Saltcedar Simulation Model Development
The saltcedar simulation model was developed by USDA-ARS staff, starting
16
with the EPIC 9200 model, and importing subroutines from the ALMANAC model
developed by Jim Kiniry (Input was given on model development by using literature
and results from studies. Excerpt from Kiniry et al. (2003):
The EPIC 9200 model simulates the water balance (including the water table depth), salinity, the nutrient balance, and the interception of solar radiation. The model simulates plant water use by trees and grasses from the soil and water table, provided the water table is within the rooting depth of the plant species. The model has a daily time step. It simulates plant growth reasonably and is implemented easily. Some important modifications were made to enable more realistic simulation of the hydrology at the three sites. Firstly, plant transpiration was increased by 67% over what the EPIC model normally simulates, in order to account for effects of advected energy from adjacent arid areas, as described in Arizona by Dugas et al. (1991). This response has also been demonstrated in central Texas by Dugas and Bland (1989).
Secondly, while not reported herein, diurnal fluctuations in water table were simulated from the daily value for transpiration from the daily value of water table before recharge, to give a maximum range of fluctuation each day. The value of daily transpiration was divided by 0.41, assuming 41 percent soil porosity, to calculate the daily fluctuation of water table.
Next, maximum ranges of water table depths over the season were set for each site based on results from Hays (2003). Water table fluctuations are calculated based on an assumed value for maximum ground water storage of 100 mm for all three sites. This affects how a water table rises after a rain. The value for the parameter for ground water storage loss was set to 0.2 mm per day for all the sites. We also allowed river flow rates or lake levels to affect ground water using river flow values from adjacent bodies of water.
Light Interception EPIC simulates light interception by the leaf canopy with Beer's
law (Monsi and Saeki, 1953) and the LAI. The greater the value of the extinction coefficient k, the more light will be intercepted at a given LAI. The trees were allowed to intercept the light first, with the grasses having the remaining light available to them. The fraction of incoming solar radiation intercepted by the leaf canopy is
Fraction = 1.0 - exp (-k * LAI) Light extinction coefficient of saltcedar was determined by the potential growth study.
Leaf Area Development Accurate prediction of light interception depends on realistic
description of leaf area. Values for saltcedar LAI are being developed from ongoing work by Schmidt Likewise, simulation of light
17
interception also requires accurate description of leaf area production and decline. The model estimates leaf area production up to the point of maximum leaf area for the growing season using Eq (2). The model generates a curve that is forced through the origin and through two points, asymptotically approaching y=1.0. The s-curve function takes the form:
F = X / (X + exp (Y1 - Y2 * X)) (2) where F is the factor for relative LAI, X is the fraction of heat units from planting to maturity, and Y1 and Y2 are the s-curve coefficients generated by EPIC. For each day, the fraction of total heat units that have accumulated is determined, denoted as SYP. The sum of heat units is zero at planting in the establishment year and at tiller emergence in subsequent years, and is maximum at maturity. The s-curve describes how LAI can increase, under nonstress conditions, as a function of SYP.
Biomass Production and Partitioning Biomass growth is simulated with a RUE approach (Kiniry et al.,
1989). Values for RUE have been previously derived for many crops (Kiniry et al., 1989; Manrique et al., 1991; and Kiniry et al., 1992). For grasses, we have used RUE values ranging from 1.8 to 5.0 g per MJ of intercepted photosynthetically active radiation (Kiniry et al., 1999).
The maximum rooting depth defines the potential depth in the absence of a root-restricting soil layer. Soil cores from plots at Temple in 1994 indicate that grass roots varied in depth among the species, with switchgrass roots extending to 2.2 m (Kiniry et al., 1999). For saltcedar, we assumed a deep maximum rooting depth 30 m to assure that plants could extract water from the water table. For the Pecos River site, we only simulated saltcedar. We assumed grass roots could extended to 2.0 m at the other two sites.
Model Testing
In order to test the simulation model a total of 156 model runs were completed
(see appendix A). The model was set up for the east side of the Pecos River in Loving
County, TX just west of Mentone adjacent to the river channel. This site has been
described by White et al. (2003). The soil was predominately sand. Flow of the Pecos
River is regulated by water releases (for irrigation) from Red Bluff Lake. Since there
were 18 years of available river flow data the simulation run was set up for 18 years.
Factors such as potential LAI (runs 107-119), minimum and maximum water table
18
depths (runs 78-106, 120-156), and soil salinity and plant salt sensitivity factors (runs
1-77) were varied to determine how they affected predicted biomass production,
potential evapotranspiration (PET), evapotranspiration, soil water evaporation, and
plant transpiration (EP).
Effect of Salinity and Water Table Depth on Saltcedar Growth and Water Use
This study was conducted in the summer of 2002 (June-December) at the
Blackland Research Center Temple, Texas. Four replications (randomized block
design) of three depths to saturated soil (0.5, 1.0, and 1.75 m) and five salinities (tap
water, 1250, 2500, 5000, 7500 ppm) of water solution were used. Saltcedar was
established from cuttings in early spring of 2002, raised in a greenhouse and
transplanted to containers by June 1.
Cutting Establishment
The cuttings, approximately 0.45 m long and at least 1.6 cm in diameter, were
taken from the United States Department of Agriculture, Agricultural Research Service
(USDA-ARS) study site near Seymour, Texas. The cuttings were placed in an ice chest,
chilled, and stored until potted. The cuttings were potted in a greenhouse as soon as
possible in a 1.0 m long by 10 cm diameter PVC sewer pipe filled with course sand.
These were irrigated daily (with bottom drainage) from Monday through Friday to
allow growth to begin as soon as possible.
Development of Experimental Unit
Plants were arranged in a complete randomized block design with 4 replications
(Figure 1). There were 15 possible treatments consisting of 5 different salinity levels
(tap-water, 1250, 2500, 5000, 7500 ppm) and 3 depths to saturated soil (approx. 0.5,
19
1.0, and 1.75 m). There were 4 plants per treatment per replication.
Physical Facilities
Plants were grown in a nursery (outside of the greenhouse) in 2.05 m long tubes
that had each respective treatment plumbed to it. Tubes were arranged in a complete
randomized block design (Figure 1). They were held up by a rack system constructed of
4”x4” and 2”x6” treated wooden boards. The plants were oriented in rows from north to
south to reduce shading. The plant rows were spaced 2.13 m apart so that each row did
not cast a shadow on other plants. Plants were placed on the end of each row and given
the same treatment, but were not sampled until the end of the study. This was done so
that each plant would have a plant next to it and receive equal treatment. The outside
plants received the lowest salinity (0 ppm) and middle water table depth (1.0 m).
Salinity Treatment
Different salinities were mixed using Morton Mixing Salt (NaCl) and tap water.
The following salinities were used: tap water (0 ppm), 1250 ppm, 2500 ppm, 5000
ppm, 7500 ppm. The salinities were mixed and stored in 5 separate containers. Each
salinity level also received Miracle-Gro All Purpose Plant Food, 15-30-15 (191.6 mg l-1
H2O) in order to insure plant growth would not be limited by lack of nutrients in a sand
medium.
Depth to Water Table
There were three depths to water tables: 0.5m, 1.0m, and 1.75 m studied.
Saturated soil was maintained by using a float bucket to supply each plant. As plants
utilized water, the floats in the respective buckets immediately refilled the bucket and
maintained a relatively constant water level (Figures 2, 3, and 4). The float valves and
20
buckets were small horse troughs that were sealed with plastic on the top to prevent
evaporation and rainfall input.
Figure 1. Layout of experimental unit for water table depth and salinity study. Salinities are designated by: S1= Tap water, S2=1250 ppm NaCl, S3=2500 ppm NaCl, S4=5000 ppm NaCl, S5=7500 ppm NaCl.
21
Sampling Procedure
On May 24, the healthiest 250 plants growing in the greenhouse had another
section of pipe filled with coarse sand added to the bottom, resulting a total length of
2.05 m. These were installed in the randomized block design experiment. The plants
were then hooked up to the water supply system.
Three harvests took place on the following dates: August 5-8, September 17,
and December 18. The first two harvests each contained ¼ of the total plants in the
study. Plants were randomly selected for harvest for each date. The last harvest
contained the last half of the plants in the study. After each of the first two samplings
the remaining plants were moved together so that each plant continued to have the same
amount of space and shading between itself and its neighbor.
Data Collection
Aboveground Biomass and Belowground Biomass
The harvested plants were partitioned into aboveground and belowground
biomass. The aboveground biomass was separated into leaves and stems, then, weighed
after being oven-dried. The belowground portion was divided into 0.25 m sections
starting at the top of the plant growth tube and going down. The sand medium on the
first two harvests was washed away using a screen. On the last harvest, the sand
medium was washed from the roots on a sloped piece of plywood (Figure 5). A screen
was not used since it was determined that the fine roots stuck to the screen and could
not be easily recovered. Roots per section per plant were oven-dried, weighed and
recorded.
22
Leaf Area
Leaves were hand stripped from each plant and then run thru a LiCor leaf area
machine to determine fresh one sided leaf area for the first two harvests. The last
harvest did not have this done since it was occurred after leaf drop.
Water Use
Water use was measured by two methods. The first method measured water use
by treatment (15 plants per treatment). This was achieved by placing a water level
logger in each of the treatment water supplies. Since there were only 5 loggers, data
could not be recorded for all the treatments at the same time. Therefore, the 5 water
loggers were placed at only one depth to the water table level each week and moved to
a new depth every 7 days. The data for days when water loggers were moved and
negative values were obtained due to logger malfunction were not used for analysis.
Only times that occurred after and before 13:00 were used for calculation of low water
use. Only values that occurred after 13:00 were used to determine time of peak average
use.
The second method was to turn off the water supply of each plant and record the
amount the water dropped in the soil profile using a sight tube. This was done twice
during the summer. Each plant’s water supply was turned off in the morning and then
the depth to the water level in the sight tube was recorded. The next day at the same
time, the water level was recorded again. The difference between these two
measurements was then calculated giving the amount of drop in the water table. This
was then multiplied by the specific yield (18%) of the soil to determine the amount of
water used. Specific yield of the coarse sand was determined by saturating a known
23
volume of soil and measuring the volume of water that freely drained over a 24-hour
period (expressed as a percent). Statistical analysis was run on the average of the two
days of readings. In order for a reading to be included, it had to be positive and not
have a leak on that sample unit.
24
Figure 2. Diagram of depth and salinity study equipment setup.
25
Figure 3. Photograph of lysimeter study, angle view showing rows of trees before initiation of study.
Figure 4. Photograph of lysimeter study, side view, showing different water levels.
26
Climatic Data
Daily maximum and minimum air temperature, maximum and minimum
relative humidity, average vapor pressure, total solar radiation received, average wind
speed, average wind direction, and total precipitation was obtained from an on-site
weather station maintained by the United States Department of Agriculture, Agriculture
Research Service (USDA-ARS) staff at Temple, Texas. These data were available
directly from the web located at: http://arsserv0.tamu.edu/hydata.htm.
Statistical Analysis
Descriptive statistics such as mean, standard deviation, standard error of the
mean, and confidence intervals were calculated for the field data study, potential
growth study, and salinity/water table depth study. One-way ANOVA’s were then
performed for each of these studies. If significance was indicated a multiple comparison
was performed using Tukey’s HSD method to discern if there were any significant
Figure 5. Demonstration of root washing technique using a slanted board.
27
differences between means. Differences were considered significant at the p<0.05 level.
For water use data, linear regression equations were developed using the stepwise
method. All analyses were performed using the Statistical Package for the Social
Sciences (SPSS) for Windows v. 11.01.
28
RESULTS
Characterization of Naturally Established Stands
The average LAI of the trees sampled across all sites was 0.31 with no
significant differences between sites (Table 2). The Seymour site had the highest
average LAI of 0.53, while the Las Cruces site had the lowest average LAI of 0.13. The
average light extinction coefficient (k) was -0.54 with no significant differences
between sites. The Seymour site had the highest average k, -0.58, while the site at Lake
Proctor had the lowest average k, -0.47. Average age of trees sampled, assuming one
growth ring equaled one year of growth, was 3.6 years. The Seymour site had the oldest
trees averaging 5.4 years while the youngest trees where sampled at the Pueblo site,
1.75 years (Table 2). There was a significant correlation at the p<0.05 level of r=0.524
between LAI and k across all sites.
Table 2. Average leaf area index, light extinction coefficient, and age of small saltcedar trees from sites in Texas, New Mexico and Colorado.
Location N LAI K Age (years) Seymour, TX 5 0.53±0.66 a -.058±0.53 a 5.4±1.1 a Lake Proctor,
TX 3 0.29±0.27 a -0.47±0.40 a 2.0±0.0 b
Las Cruces, NM
4 0.13±0.06 a -0.55±0.31 a 3.0±0.0 b
Pueblo, CO 4 0.29±0.20 a -0.52±0.13 a 1.8±1.0 b Canadian river,
TX 2 0.18±0.13 a -0.57±0.14 a 6.0±0.0 a
Overall 18 0.31±0.38 -0.54±0.33 3.6±1.9 Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
The ratio of leaf area to fresh weight averaged 16.8 cm2 g-1 across all sites and
samples (Table 3). The samples from Las Cruces had a significantly higher ratio than
29
samples from the other sites. The ratio from Lake Proctor was significantly lower than
the average ratios from the Canadian River and Las Cruces.
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
Characterization of Artificially Established Stands
Saltcedar had lower LAI values than cottonwood or willow, but the highest light
extinction coefficient (Table 4). Cottonwood had the highest LAI but the lowest light
extinction coefficient. If Tamarix spp. are separated into the two types used in this
study, the saltcedar cuttings from Seymour, TX had the lowest LAI across among all
plants and had a lower light extinction coefficient than Tamarix ramosissima from
California. There were statistically significant differences between species for LAI
whether both types of saltcedar where lumped together or analyzed separately, though
no significant difference between saltcedar types. There were significant differences
between saltcedar and Salix nigra for light extinction coefficient. There was no
significant difference between Populus deltoides and any of the species with regards to
radiation use efficiency, whether both types of saltcedar were lumped together or not.
Table 3. Means of the ratio of saltcedar leaf area to fresh weight (cm2 g-1) from five sites.
Location N Mean Wichita river Seymour, TX 17 16.1±2.1 a,b
Lake Proctor, TX 3 13.9±0.6 a Las Cruces, NM 4 21.8±1.6 c
Pueblo, CO 5 15.7±1.5 a,b Canadian river, TX 10 17.6±0.7 b
Overall 39 16.8±2.5
30
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns. Effect of Salinity and Water Table Depth on Saltcedar Growth and Water Use
Water Use
Minimum and Maximum Rate of Recharge
The amount of recharge to the saturated soil profile in each plant container is a
direct measure of the water use by the plant but recharge occurs after transpiration and
root water uptake. The average minimum recharge rate per hour was 0.70 ml hr-1 per
tree and occurred at 06:15 while the average maximum rate was 15.84 ml hr-1 per tree
and occurred at 19:20 (Table 5). When ANOVA was calculated there was no
indication of linearity between the maximum time and salinity. There was a significant
difference between the 1.00 m and the 1.75 m water table depth and time of peak
occurrence of water use, the 1.00 m water table occurred at 19:55 while the 1.75 m
water table depth occurred at 18:19 (Table 6).
Table 4. Average leaf area index (LAI) and light extinction coefficients (k) of Tamarix spp. from Seymour, Texas, Tamarix ramosissima, Salix spp., and Populus spp.
Tree Species N LAI K Tamarix spp.
(Seymour, TX) 12 0.09±0.05 a -0.74±0.48 a
Tamarix ramosissima (CA)
12 0.11±0.08 a -0.78±0.32 a
Salix nigra (Temple, TX)
12 0.50±0.35 b -0.36±0.12 b
Populus deltoids (Temple, TX)
3 0.57±0.17 b -0.33±0.14 a,b
Overall 39 0.26±0.29 -0.60±0.38
31
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
Water
table depth m
N MIN TIME MAX TIME Minimum ml/hr/plant
Maximum ml/hr/plant
0.50 21 5:11±3:39 a 19:40±2:03 a,b 0.92±1.18 a 15.17±5.87 a
1.00 40 6:27±4:06 a 19:55±2:07 a 0.88±1.32 a 16.26±7.64 a 1.75 30 6:42±3:40 a 18:19±1:51 b 0.31±0.89 a 15.74±13.23 a
Mean 91 6:15±3:52 19:20±2:07 0.70±1.18 15.84±9.46 Values are means ± SD. Means with same letter significantly different (p<0.05) within columns.
Daily Recharge
Using logger data the average amount of recharge (water use) per plant per day
was 80 ml (Table 7). Plants in the 1.25 ppt salinity level used significantly more water
(109 ml per day per plant) than plants in other salinity levels. Plants utilizing a 1.75 m
water table used significantly less water (57 ml per day per plant) than plants with other
water table levels.
Table 5. Average minimum and maximum hourly rates of recharge of the soil profile (water use) per day and time of occurrence with filtered observations across salinities.
Salinity ppt
N MIN TIME MAX TIME Minimum ml/hr/plant
Maximum ml/hr/plant
.00 16 6:41±3:25 a 18:24±2:11:45 a 1.09±1.75 a 17.24±13.14 a 1.25 31 5:39±4:04 a 19:39±1:51 a 0.69±0.79 a 17.20±9.61 a 2.50 18 7:27±2:60 a 19:41±1:49 a 0.57±1.23 a 14.44±6.80 a 5.00 10 5:30±3:50 a 19:45±1:13 a 0.32±0.79 a 14.67±9.70 a 7.50 16 6:04±4:45 a 18:60±3:01 a 0.72±1.30 a 14.12±7.69 a
Mean 91 6:15±3:52 19:20±2:07 0.70±1.18 15.84±9.46
Table 6. Time of peak and minimum recharge (water use), and average minimum and maximum recharge (water use) rates.
32
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
When a predictive equation was developed for daily recharge (ml day-1) using
salinity and water table depth as the independent variables, the r2 was extremely low
(0.050) (Table 8). Including climatic data for the site resulted in a multiple regression
equation (stepwise method) with an r2 of 0.568 (Table 9). The variables in this
predictive equation are as follows:
Previous1 Total Solar Radiation (kJ m-2), Water Table depth (m), Average Wind
Speed (m s-1), Salinity (ppt), Previous Total Precipitation (mm), Previous
Average Wind Speed (m s-1), Previous Average Vapor Pressure (kPA),
Minimum Relative Humidity (%), Previous Average Wind Direction (Degrees),
and Maximum Air Temperature (C).
The coefficients for each variable within each equation showed all variables,
except the previous days average vapor pressure, had a negative influence on water use,
1 Previous= average for the day before.
Salinity ppt N ml of H2O day-1 0.00 63 67.8±72.4 a 1.25 107 109.4±81.3 2.50 108 76.5±65.2 a 5.00 63 71.3±62.2 a 7.50 103 67.3±61.0 a
Water Table Depth m 0.50 120 92.7±76.1 a 1.00 206 86.5±72.8 a 1.75 118 56.6±55.0 b
Overall 444 80.3±70.8
Table 7. Average daily recharge (water use by saltcedar) for each salinity and water table level.
33
Sight Tube Data
Only two days of data were obtained from sight tube measurements. Average
water use on 7/18/02 was 94 ml, average water use on 7/25/02 was 155 ml. The average
Table 8. Regression equation for recharge (water use by saltcedar) (ml d-1) using the enter method with salinity and depth to the water table as the independent variables.
Unstandardized Coefficients
B Std. Error (Constant) 124.016 9.293
Salinity (ppt) -3.278 1.221 Water table depth
(m) -30.727 7.104
r2 Adjusted r2 Standard Error of the Estimate
0.054 0.050 69.050
Table 9. Regression equation for recharge (water use by saltcedar) (ml d-1) using the stepwise method with salinity, depth to the water table and climatic data as the independent variables.
Unstandardized Coefficients
Standard error R2
(Constant) 93.856 16.703 Prev Total Solar Rad. (kJ/m2) 4.734E-03 0.001 0.398
Min RH(%) -0.753 0.161 0.544 Prev Avg Wind Dir. (deg) -9.170E-02 0.028 0.561
Max Air Temp (C) -2.422 0.846 0.568
r2 Adjusted r2 Standard Error of the Estimate
0.568 0.558 47.106
34
was 125 ml of water per plant per day. While there were trends of decreasing water use
with increasing salinity there were no statistically significant differences between
salinities (Table 10). There were significant differences between water table depths
(Table 11). On 7/18/02 plants with a 1.00m water table used 67 ml, which was
significantly lower than plants using water from the 0.5m level (120 ml). On 7/25/02
saltcedar used significantly less water (87.55 ml) with a 1.75 m water table compared to
plants with a water table depth of 0.50 m (170 ml) or 1.00m (168 ml). When the two
days were averaged, 96 ml was used by plants in the 1.75 m water table treatment,
which was significantly lower than the 145 ml of water use by plants with a 0.50 m
water level.
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
Table 10. Average recharge (water use by saltcedar) (ml/plant) across salinities for the sight tubes.
Salinity ppt N Use (ml) on 7/18
Use (ml) on 7/25
Average of 7/18 and 7/25 (ml)
0.00 37 103±77 a 180±105 a 141±80 a 1.25 30 130±235 a 144±87 a 137±119 a 2.50 28 89±66 a 166±69 a 127±61 a 5.00 25 85±56 a 147±39 a 116±42 a 7.50 29 58±39 a 133±47 a 95±41 a
Overall 149 94±120 155±77 125±77
35
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
Biomass
There where some statistical differences in biomass variables between harvest
dates (time from establishment). Cutting size of the original stem material, total stem
weight, and length of the longest stem increased with each harvest (Table 12, 13, 14,
15). Roots at the 0.75-1.0 m and the 1.0-1.25 m soil depth and total stem counts
decreased with successive .
Root biomass distributions differed among water table depth treatments. Root
biomass was greatest in the 0.50-0.75 m zone for plants with a 0.50 m water table, in
the 0.75-1.0 m with a 1.00 m water table, and in the 0.25-0.50 m and 1.50-1.75 m soil
profile for the 1.75 m water table (Figure 6). Root distributions did not differ between
salinity levels, except for the 1.25 ppt level, which had a significant peak in the 0.50-
.75 m zone (Figure 7). The second harvest date had a higher peak biomass of roots than
the other harvest dates (Figure 8).
There where no significant differences in root biomass variables between
Table 11. Average recharge (water use by saltcedar) (ml/plant) with increasing water table depths for the sight tubes.
Water table depth m
N Use (ml) on 7/18
Use (ml) on 7/25
Average of 7/18 and 7/25
(ml) 0.00 37 120±63 a 170±74 a 145±61 a
1.00 30 67±49 b 168±78 a 118±58 a,b
1.75 28 105±263 a,b 88±41 b 96±129 b
Overall 149 94±120 155±77 125±77
36
salinity treatments, harvest dates or within harvest dates (Table 16, 17). There where
significant differences in root biomass between depths to the water table among harvest
dates and within each harvest. Root to shoot ratios were not statistically different
between salinity levels or water table depths.
There were significant correlations between average water use from the sight
tube data and salinity (-0.218), water table depth (-0.228), cutting weight (0.208), roots
in the 0.25-0.75 m zone (0.257), total amount of roots (0.262), stem weight (0.328), leaf
weight (0.311), leaf area (0.283), and length of longest stem (0.241). There were
significant correlations between salinity and cutting weight, root biomass in soil profile
section B (0.194), root biomass in section C (0.166), and root biomass in section E (-
.185). There were also significant correlations between water table depth and cutting
biomass, root biomass in section B (-0.267), root biomass in section B (-0.424), root
biomass in section C (-0.346), root biomass in section F (0.213), root biomass in
section G (0.401), root biomass in section H (0.384), total root biomass (-0.197), total
stem biomass (-0.415), total leaf area (-0.302), and length of longest stem (-0.236).
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
Harvest N Cutting section 0-.25m (g)
Cutting Section 0.25-.50 (g)
Total Cutting (g)
August 5 59 66.80±28.81 a 29.06±16.88 a 96.50±33.88 a September 17 51 74.61±32.14 a,b 31.59±21.60 a,b 107.36±40.30 a December 18 130 87.18±47.35 b 38.34±22.66 b 125.97±55.16 b
Overall 240 79.50±41.28 34.63±21.47 114.86±49.29
Table 12. Average cutting sizes for each harvest date following establishment of saltcedar in June 2002.
37
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
Values are means ± SD. Means with same letter are significantly different (p<0.05) within columns.
Harvest Date 2002
N Roots Section D 0.75-1.0m (g)
Roots Section E 1.25-1.50m (g)
August 5 59 4.97±4.97 b 0.91±1.49 a September 17 51 2.98±3.18 a 0.31±0.55 b December 18 130 3.35±2.93 a 0.67±1.14 a,b
Overall 240 3.67±3.65 0.65±1.16
Table 13. Average amount of saltcedar roots in sections D and E for each harvest.
Table 14. Average saltcedar stem weight, number and length for each harvest date.
Harvest Date 2002
N Total Stems (g) Number of Main Stems
Length of Longest stem
(m) August 5 59 11.17±7.00 b 5.6±2.2 a,b 0.37±0.12 b
September 17 51 16.47±9.74 a 6.4±2.6 b 1.03±0.33 a December 18 130 16.84±9.92 a 5.1±2.0 a 0.98±0.33 a
Overall 240 15.39±9.53 5.5±2.3 0.84±0.40
38
Table 15. Average saltcedar biomass (g) for all harvest dates, salinities, and water table depths.
Cutting SectionA(0-.25m) in gCutting SectionB(.25-.50m) in gCutting SectionC(.50-1.0m) in gTotal Cutting Weight in gRoots Section A(0-.25m) in gRoots Section B(.25m-.50m) in gRoots Section C(.50-.75m) in gRoots Section D(.75m-1.0m) in gRoots Section E(1.0-1.25m) in gRoots Section F(1.25-1.5m) in gRoots Section G(1.5-1.75m) in gRoots Section H(>1.75m) in gTotal Dry roots in gTotal Stems in gTotal dry leaves in gleaf area in cm^2Number of Main stemsLength of Longest stemin mRoot to shoot ratioValid N (listwise)
Table 17. Average saltcedar top growth across all harvest dates and salinities for each water table depth.
44
Table 18. Mean annual and mean daily plant water use (transpiration) (mm) as estimated by the saltcedar simulation EPIC model, for the Pecos River site with different saltcedar cover (LAI) and for the Colorado and Canadian sites with representative plant cover (Kiniry 2003).
Tree LAI: 0.5 1 2
3 4 5
Mean Annual (mm yr-1)
377 688 1286 1889 2203 2260 Pecos River
Mean Daily (mm d-1)
2.5 4.7 8.8 13.0 14.8 14.7
Mean Annual (mm yr-1) (LAI=1.0 for trees and 1.0 for grass)
1060 Colorado River
Mean Daily (mm d-1)
7.1
Mean Annual (mm yr-1) (LAI=0.5 for trees and 3.0 for grass)
1404 Canadian River
Mean Daily (mm d-1)
12.2
45
Saltcedar Simulation Model Sensitivity
The saltcedar simulation model developed by Kiniry (2003) was evaluated by
varying the plant sensitivity factor, soil salinity, minimum and maximum water table
depth, and potential leaf area index. Each time a new factor was adjusted other factors
were held constant as per the original model.
Plant Salt Sensitivity Factor and Soil Salinity
As the plant salt sensitivity factor ranged from 0.0 to 0.5 (t ha-1)/(mmho cm-1)
and initial soil salinity ranged from 0.0 to 10.0 mmho cm-1, soil water evaporation
increased by a factor greater than 5 (Figure 9). Plant transpiration showed a decreased
36 fold from 2263 mm yr-1 to 62 mm yr-1 (Figure 10). Evapotranspiration also
decreased from 2347 mm yr-1 to 554 mm yr-1, a factor of 4 (Figure 11). Potential
evapotranspiration showed an increase as plant salt sensitivity and soil salinity
increased. PET ranged from 2321 mm yr-1 to 2533 mm yr-1 (Figure 12). Biomass
production decreased as plant salt sensitivity and soil salinity increased. When plant salt
sensitivity and soil salinity were low the model predicted 10.4 t ha-1of biomass
production compared to zero production when plant salt sensitivity and soil salinity
where both high (Figure 13).
46
Figure 9. Effect of plant salt sensitivity factor and soil salinity on the saltcedar simulation model’s predicted soil water evaporation.
0
100
200
300
400
500
600
02
46
810
12
0.00.1
0.20.3
0.40.5
0.6
Aver
age
Annu
al S
oil W
ater
Eva
pora
tion
(mm
yr-1
)
Soil S
alinit
y (m
mho cm
-1 )Plant Salt Sensitivity Factor ((t ha -1)/(mmho cm -1))
47
Figure 10. Effect of plant salt sensitivity factor and soil salinity on saltcedar simulation model’s predicted plant transpiration.
0
500
1000
1500
2000
2500
02
46
810
12
0.00.1
0.20.3
0.40.5
0.6
Aver
age
Annu
al P
lant
Tra
nspi
ratio
n (m
m y
r-1)
Soil Salinity (m
mho cm-1 )
Plant Salt Sensitiviy Factor ((t ha -1)/(mmho cm -1))
48
Figure 11. Effect of plant salt sensitivity factor and soil salinity on saltcedar simulation model’s predicted evapotranspiration.
400600800
1000
1200
1400
1600
1800
2000
2200
2400
2600
02
46
810
12
0.00.1
0.20.3
0.40.5
0.6
Aver
age
Annu
al E
vapo
trans
pira
tion
(mm
yr-1
)
Soil Salinity
(mmho cm-1 )Plant Salt Sensitivity Factor ((t ha -1)/(mmho cm -1))
49
Figure 12. Effect of plant salt sensitivity factor and soil salinity on saltcedar simulation model’s predicted potential evapotranspiration.
2300
2350
2400
2450
2500
2550
0
24
68
1012
0.00.1
0.20.3
0.40.5
Aver
age
Annu
al P
oten
tial E
vapo
trans
pira
tion
(mm
yr-1
)
Soil S
alinit
y (mmho
cm-1 )
Plant Salt Sensitivity ((t ha -1)/(mmho cm -1))
50
Figure 13. Effect of plant salt sensitivity factor and soil salinity on saltcedar simulation model’s predicted biomass production.
0
2
4
6
8
10
12
02
46
810
12
0.00.1
0.20.3
0.40.5
0.6
Aver
age
Annu
al B
iom
ass
Yiel
d (t
ha-1
yr-1
)
Soil Salinity (m
mho cm-1 )
Plant Salt Sensitivity ((t ha -1)/(mmho cm -1))
51
Minimum and Maximum Water Table Depth When minimum water table depth (m) was adjusted from 0.01 m to 3.0 m,
saltcedar biomass production, PET, and plant transpiration varied little: 10.3-10.4 t ha-1,
2323-2321 mm yr-1, and 2258-2263 mm yr-1 respectively (Figures 14,15,16) Soil water
evaporation decreased as minimum water table depth was increased. It ranged from 154
mm yr-1 to 59 mm yr-1 (Figure 17).
Maximum water table depth was varied from 0.0m to 15.0 m. As maximum
water table depth increased predicted biomass remained constant at 10.4 t ha-1 until the
water table was at 3.6 m, where a decline to 4.8 t ha-1 occurred. Biomass then
exponentially decreased to 0.8 t ha-1 for a water table depth of 6.14 m, then remained
Figure 14. Effect of initial depth to the water table on the saltcedar simulation model predicted biomass production.
Minimum Water Table Depth (m)
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5
Aver
age
Annu
al B
iom
ass
Yiel
d (t
ha-1
yr-1
)
10.28
10.30
10.32
10.34
10.36
10.38
10.40
10.42
52
constant (Figure 18). PET essentially did the opposite by increasing in a stair step
fashion until reaching a plateau of 2435 mm yr-1 when the water table was at 6.14m
(Figure 19).
Soil water evaporation started out high (171 mm yr-1) at the shallowest
maximum water table depth then decreased to a low when the maximum depth varied
between 3 to 6 m (59 mm yr-1). As the maximum water table depth increased from 6 to
15 m soil water evaporation remained constant (84 mm yr-1) (Figure 20).
The effects of the change in maximum water table depth on plant transpiration
was similar to the effects on predicted saltcedar biomass. As maximum water table
depth increased plant transpiration remained constant (approx. 2263 mm yr-1) until the
Figure 15. Effect of minimum depth to the water table on potential evapotranspiration using the saltcedar simulation model.
Minimum Water Table Depth (m)
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5Aver
age
Annu
al P
oten
tial E
vapo
trans
pira
tion
(mm
yr-1
)
2321.0
2321.5
2322.0
2322.5
2323.0
2323.5
53
3.6 m depth where it stair stepped down to 1354 mm yr-1at the 4 m depth. Plant
transpiration then appeared to exponentially decrease to 176 mm yr-1 at 6.14m and then
remained constant (Figure 21).
Figure 16. Effect of minimum depth to the water table on plant transpiration using the saltcedar simulation model.
Minimum Water Table Depth (m)
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5
Aver
age
Annu
al P
lant
Tra
nspi
ratio
n (m
m y
r-1)
2250
2252
2254
2256
2258
2260
2262
2264
54
Figure 17. Effect of minimum depth to the water table on soil water evaporation using the saltcedar simulation model.
Minimum Water Table Depth (m)
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5
Aver
age
Annu
al S
oil W
ater
Eva
pora
tion
(mm
yr-1
)
40
60
80
100
120
140
160
180
55
Figure 18. Effect of maximum depth to the water table on biomass production using the saltcedar simulation model.
Maximum Water Table Depth (m)
0 2 4 6 8 10 12 14 16
Aver
age
Annu
al B
iom
ass
Yiel
d (t
ha-1
yr-1
)
0
2
4
6
8
10
12
56
Figure 19. Effect of maximum depth to the water table on potential evapotranspiration using the saltcedar simulation model.
Maximum Water Table Depth (m)
0 2 4 6 8 10 12 14 16Aver
age
Annu
al P
oten
tial E
vapo
trans
pira
tion
(mm
yr-1
)
2300
2320
2340
2360
2380
2400
2420
2440
2460
57
Figure 20. Effect of maximum depth to the water table on soil water evaporation using the saltcedar simulation model.
Maximum Water Table Depth (m)
0 2 4 6 8 10 12 14 16
Aver
age
Annu
al S
oil W
ater
Eva
pora
tion
(mm
yr-1
)
40
60
80
100
120
140
160
180
58
Figure 21. Effect of maximum depth to the water table on plant transpiration using the saltcedar simulation model.
Maximum Water Table Depth (m)
0 2 4 6 8 10 12 14 16
Aver
age
Annu
al P
lant
Tra
nspi
ratio
n (m
m y
r-1)
0
500
1000
1500
2000
2500
59
Potential Leaf Area Index
Thirteen runs of the saltcedar simulation model were completed by adjusting the
leaf area index from 0.5 to 12.0. As LAI increased, PET and soil water evaporation
decreased in an exponential fashion (Figure 22, 23). Predicted ET increased in a linear
fashion until the LAI reached 4 when the slope changed and then continued in a linear
fashion but with a different slope (Figure 24). Plant transpiration also increased in a
linear fashion until the LAI reached 4 when the slope changed and then continued in a
linear fashion but with a different slope (Figure 25). As leaf area index increased,
biomass increased (Figure 26). ET did not exceed PET until the LAI reached 5 (Figure
Figure 22. Effect of potential leaf area index on potential evapotranspiration using the saltcedar simulation model.
Potential Leaf Area Index (LAI)
0 2 4 6 8 10 12 14Aver
age
Annu
al P
oten
tial E
vapo
trans
pira
tion
(mm
yr-1
)
2200
2250
2300
2350
2400
2450
2500
2550
60
27).
Figure 23. Effect of potential leaf area index on evapotranspiration using the saltcedar simulation model.
Potential Leaf Area Index (LAI)
0 2 4 6 8 10 12 14
Aver
age
Annu
al E
vapo
trans
pira
tion
(mm
yr-1
)
600
800
1000
1200
1400
1600
1800
2000
2200
2400
2600
61
Figure 24. Effect of potential leaf area index on plant transpiration using the saltcedar simulation model.
Potential Leaf Area Index (LAI)
0 2 4 6 8 10 12 14
Aver
age
Annu
al P
lant
Tra
nspi
ratio
n (m
m y
r-1)
0
500
1000
1500
2000
2500
3000
62
Figure 25. Effect of potential leaf area index on soil water evaporation using the saltcedar simulation model.
Potential Leaf Area Index (LAI)
0 2 4 6 8 10 12 14
Aver
age
Annu
al S
oil W
ater
Eva
pora
tion
(mm
yr-1
)
0
50
100
150
200
250
300
350
400
63
Figure 26. Effect of potential leaf area index on biomass production using the saltcedar simulation model.
Potential Leaf Area Index (LAI)
0 2 4 6 8 10 12 14
Aver
age
Annu
al B
iom
ass
Yiel
d (t
ha-1
yr-1
)
2
4
6
8
10
12
14
64
Figure 27. Plot of the difference of PET minus ET (mm) versus potential leaf area index using the saltcedar simulation model.
Potential Leaf Area Index (LAI)
0 2 4 6 8 10 12 14
Aver
age
Annu
al P
ET -
ET (m
m y
r-1)
-500
0
500
1000
1500
2000
65
DISCUSSION and CONCLUSIONS
Characterization of Naturally and Artificially Established Stands
Leaf area indices from all collection sites were low compared to reported values
for saltcedar, but this is not unreasonable since small isolated trees were sampled. If
larger trees were sampled LAI should have increased. Light extinction coefficients (k)
were similar across all sites, with the mean being -0.54. This was lower than the light
extinction coefficient of the artificially established trees (-0.76), suggesting that
naturally occurring trees were being limited, since the artificially established trees were
of similar form and stature as the natural trees sampled. Based on these studies, young
isolated saltcedar trees intercept approximately 50% of the incident light that reaches
their canopy. LAI and k were correlated which was expected since the LAI increased
over a given area the more leaf area there is to intercept light thus increasing the light
extinction coefficient. The ratio of leaf area to fresh weight (16.8 cm2 g-1) can be used
to estimate leaf area in the field by weighing the fresh weight of the leaves and then
calculating the leaf area. If the area over which the sample was collected was known,
then you could easily estimate the LAI for the site by dividing leaf area by the area of
the sample.
Since the light extinction coefficient of saltcedar was significantly higher with a
lower LAI than Salix spp. or Populus spp. this apparently gives saltcedar a competitive
advantage with greater light interception per unit of leaf area. This could give saltcedar
the ability to shift more energy to other areas of growth (i.e. roots) and, thus, not be
limited by that factor as much.
66
Effect of Salinity and Water Table Depth on Saltcedar Growth and Water Use
Saltcedar demonstrated a diurnal pattern in the rate of discharge from the water
supply tubes (water use), with discharge occurring in the early morning and the low
occurring late afternoon/early evening. This peak discharge time is different from Gay
and Sammis (1977) and Smith (1989) which reported that peak transpiration occurred
around noon. White et al. (2003) found the diurnal cycle in the shallow groundwater
table to occur in late afternoon or evening. The lag time between transpiration and
changes in the water table have not been adequately documented. Salinity did not have
any significant effect on the timing or the minimum or maximum rate of discharge
(water use). Hagemeyer and Waisel (1987) reported that salinity did not affect the
timing of saltcedar transpiration but did dampen its transpiration rates.
As salinity increased to 1.25 ppt, water use (with the water logger discharge
records) peaked at 109 ml of water per day then decreased to a level nearly equal to the
0.0 ppt level even though salinity was 7.5 ppt. This seems to indicate that salinity may
increase water use up to a certain point and then decrease water use once this
“optimum” is reached. However, the sight tube results for two days in July did not
indicate this (Figure 28). The sight tubes indicated a trend of decreasing water use as
salinity increased, with the peak water use at the lowest salinity level.
Water table depth had a significant effect on water use. Both the sight tubes and
water loggers indicated that as water table depth increased water used decreased
(Figure 30). This research supports the findings of numerous authors that indicated
depth to the water table is a major factor affecting saltcedar water use.
67
Figure 28. Average water use of saltcedar using water loggers and sight tubes for each salinity level across all water table depths.
Figure 29. Average water use of saltcedar using water loggers and sight tubes for each water table depths across all salinities.
020406080
100120140160
Average Water
Use (ml d-
1)
0.50 m 1.00 m 1.75 m
Logger DataSight Tube
020406080
100120140160
Average Water
Use (ml d-
1)
0.0ppt
1.25ppt
2.5ppt
5.0ppt
7.5ppt
LoggerSight tube
68
The average use of 77 ml day-1 for the sight tube results is close to the water logger
average for the whole season of 71 ml day-1. Thus the two methods appear to validate
each other. A comparison of this research with other studies in shown in Figure 30.
The regression equations from four of the studies have very similar interception points
and slope, indicating that regardless of many other factors depth to the water table may
be useful in estimating water use. These regressions should not be extrapolated beyond
a 2.5 meter depth to the water table. Numerous studies indicate saltcedar water use still
occurs at depths greater than 7 meters. A combined regression equation showed an
interception point of 364.2 cm/yr (water table at the soil surface) (for a very shallow
water table on the Canadian River in Texas, White et al. (2003) estimated growing
season water use by saltcedar and associated vegetation was 350.5 cm/yr to 420.6 cm/yr
in 2001). In addition, the saltcedar simulation model predicted water use in relation to
changes in depth to the water table. Regression of these results produced the following
equation: water use (cm/yr) = 263.5+-47.18*depth_in m with an r-square of 0.86.
More research is needed across an array of situations to determine if this single variable
can be used in new situations to estimate the impact of saltcedar on groundwater
availability. However, White et al. (2003) identified several factors that would need to
be measured and comparison between sites based on common standards, i.e., length of
growing season.
69
GatewoodLoggerSight TubeVanHylckama
study
Linear Regression
0.00000 2.00000 4.00000 6.00000
Water Table Depth (m)
-200.0
-100.0
0.0
100.0
200.0
300.0
Ave
rage
Ann
ual E
vapo
tran
spira
tion
(cm
/yr)
Use in cm = 364.16 + -93.11 * depth_inR-Square = 0.67
Use in cm = 355.02 + -59.78 * depth_inR-Square = 0.47
Use in cm = 265.78 + -71.58 * depth_inR-Square = 0.94
Use in cm = 385.91 + -90.87 * depth_inR-Square = 0.97
Use in cm = 362.23 + -99.19 * depth_inR-Square = 0.96
Figure 30 Regression equations for this study and other studies using water table depth to predict average annual saltcedar water use (cm yr-1).
When a predictive equation for saltcedar daily water use was developed using
salinity and water table depth as the dependent variables it explained very little of the
variation (r2 = 0.050). Other authors have noted daily fluctuations in water use even
when the water table was relatively steady. An equation that explains much more of
the variability (r2=0.568) resulted when climatic data from the current day and the
previous day are included (in a stepwise procedure). That the later equation included
more variables from the previous day than variables from the day of occurrence
indicating that the previous days weather may have just as great or maybe greater
influence on current day’s water use. The previous amount of solar radiation explained
the most variability with water table depth, average wind speed, and salinity following.
70
Original saltcedar transplant material increased in biomass indicating that
growth of the original stems continued throughout the study. Total stem weight
increased after each harvest even though total number of branches decreased indicating
that even though plants were losing total number of stems as the season progressed they
were able to compensate for this by increasing growth of the remaining stems.
Root biomass generally peaked at the water table interface. The 1.75 m water
table level was an exception although there was a second a peak at the water table
interface. This could be an artifact due to greenhouse plants with an accumulated root
mass at the bottom of the 1m long tubes that did not disappear after adding the
additional meter of soil and moving the water table from a one meter depth to the 1.75
meter depth. It also could be due to the taproots weighing more than fine roots that had
to extend into the new soil profile. The dominant amount of fine root biomass was
observed at the water table level for all depths (Figure 31). The saltcedar plants also
had roots extending into the saturated soil profiles. This could be a survival mechanism
to insure that if the water table were to drop the plants would continue to survive and
grow.
Salinity levels did not significantly affect biomass for any harvest date or
harvest dates combined. This would lend credence to the classification of saltcedar as a
halophyte.
Water table depth affected distribution of roots, total amount of roots, stem
weights, leaf weight, leaf area, and height of the plant. This indicates that water table
depth has a very significant effect on plant growth form. There were positive
71
correlations between sight tube water use and root weight, stem weight, leaf area, and
leaf weight indicating that as biomass increased transpiration increased.
72
Figure 31. Photograph of root distribution of saltcedar grown in an individual lysimeter. Note the fine root biomass at the bottom of the tube; this was at the water table level.
73
Saltcedar Simulation Model Testing
The saltcedar simulation model prediction of water use for the Pecos River
approximated water use reported by White et al. (2003) when a high LAI was used.
White et al (2003) reported an average of 2399 mm of water use per growing season
compared to the model prediction of 2260 mm per year with a LAI of 5. The model had
much higher predicted use (1060 mm) for the Colorado River than White et al (2003)
showed (438 mm per growing season). This could be due to the water table being set
for 1.0 m compared to the reported depth to the water table of 6.7 m and a LAI for grass
was set at 3 when grasses are minimal and only access surface water from precipitation.
The model predicted 1404 mm of water use on the Canadian river, which is less than
half the estimate of 3043 mm (White et al 2003). This is most likely due to the very low
LAI used in the model and the model failing to increase water use when the water table
was shallower than 2.0m. The site at the Canadian river probably has one of the highest
LAI for sites studied. The Canadian River site has a mix of saltcedar, cottonwood,
willow, Russian olive, buttonbush, and grasses. It also has the shallowest water table
and lowest salinity.
Generally the model functioned in the manner expected: ET, transpiration, and
biomass decreased as soil salinity and the plant’s salt sensitivity factor increased. The
plant salt sensitivity factor is critical. If the plants salt sensitivity is set too high or too
low, the effect of soil salinity and transpiration and biomass could be underestimated. .
Increasing soil salinity and plant salt sensitivity unexpectedly increased PET. It is not
clear how these are linked and why this happened since PET is calculated from weather
variables.
74
Minimum water table depth when varied over 0.0-3.0 m did not have much
effect on biomass unless the water table was extremely high and even then it only
caused a decrease in production of 0.10 ton ha1. PET and soil water evaporation
behaved in an expected manner. Transpiration increased by 1 cm until the 1.0 m water
table depth and then remained stable.
When maximum water table depth was varied over 0-15 m two critical points
became apparent: 3.75 m and 6.0 m maximum water depths. At these points biomass
would stair step down. At the 6.0 m water level saltcedar was predicted to no longer be
able to access the water table and had to subsist on rainfall, which produced a very low
biomass. PET increased as water table depth increased possibly due to increased soil
water evaporation. Soil water evaporation decreased until around six meters due two
lack of plant transpiration, that is water that normally would have been transpired by
saltcedar just evaporates from the soil surface. Transpiration by saltcedar decreased in a
stair step fashion until water the water table reached approximately 6.0 m at which
point the model predicts the plant can no longer access the water table and must subsist
on rainfall alone and thus can only transpire as much rainfall it captures.
Leaf area index affected PET, ET, transpiration, soil water evaporation, and
biomass in an expected manner. PET and soil water evaporation each decreased as LAI
increased. At a LAI of around 5 or so it should be noted that ET, transpiration, and
biomass began to level of. It is not clear to me why this is necessarily so except
indicating that there is an upper limit to the amount of water that can be transpired from
a site and the amount of biomass that can be produced. When ET is subtracted from
PET it was found that ET did not exceed PET until a LAI of around 4 was reached.
75
Overall Conclusions
1. Increasing depth to the water table was the major factor that
decreased saltcedar growth and water use.
2. Depth to the water table appears from this study and others to
explain most the variation in seasonal estimates of saltcedar water
use, while climatic factors appear to explain daily variation in
water use.
3. Increasing salinity slight decreased saltcedar water use.
4. Salt cedar’s transpiration functioned in a diurnal rhythm though
the timing of this rhythm is probably site and season specific.
5. With more energy efficiency saltcedar has a competitive
advantage over willow and cottonwood.
6. The saltcedar simulation model reasonably predicted water use
when LAI was adjusted to observed field conditions and water
tables were greater than 2.0 m. but less than 4 m.
Recommendations
Salinity and Water Table Depth Experiment
1. Use water loggers on all water supplies instead of rotating them across levels to
reduce missing data and have concurrent data sets for the same atmospheric
conditions.
2. Use a wider range of depths to the water table and salinity.
3. Use cuttings from one parent tree to avoid genetic variability.
76
4. Establish all cuttings in complete lysimeters to be used through out the study to
avoid transplanting stress and artifact root biomass distribution.
5. Prevent rainfall input to the lysimeters.
6. Sort root biomass into fine roots versus tap roots.
7. Grow plants for more than one growing season.
Saltcedar Simulation Model Development
1. Ascertain what the appropriate salt sensitivity factor is for saltcedar, since this
greatly affects the results.
2. Water table depth functions need to be improved since experimental and
literature results indicate that water table depth is a major factor.
3. Advection energy adjustments to estimate water use need to be refined to allow
effects up to two times PET. Research on the advective energy factor for
different saltcedar/riparian situations is needed to provide guidance.
4. Soil/water evaporation losses for very shallow water tables that encompasses
the stream channel water evaporation and recharge of surrounding soil profiles
need to be explored for different situations.
77
LITERATURE CITED
Anderson, J.E. 1977. Transpiration and photosynthesis in saltcedar. Proceedings of the 1977 meetings of the Arizona Section of the American Water Resources Association and the Hydrology Section of the Arizona Academy of Science held in Las Vegas, Nevada, April 15-16. Hydrology and Water Resources in Arizona and the Southwest. 7:125-131.
Anderson, J.E. 1982. Factors controlling transpiration and photosynthesis in Tamarix spp.
Chinensis Lour. Ecol. 63(1):48-56. Busch, D.E., Ingraham, N.L., Smith, S.D. 1992. Water uptake in woody riparian phreatophytes
of the southwestern United States: a stable isotope study. Ecol. Applications 2(4):450-459.
Busch, D.E., and Smith, S.D. 1995. Mechanisms associated with decline of woody species in
riparian ecosystems of the southwestern U.S. Ecol. Monogr. 65(3):347-370. Carman, J.G. and Brotherson, J.D. 1982. Comparison of sites infested and not infested with
Seasonal estimates of actual Evapotranspiration from Tamarix spp. ramosissima stands using 3-dimensional eddy covariance. J. of Arid Environ. 52:181-197.
2002. Evapotranspiration at the land/water interface in a semi-arid drainage basin. Freshwater Biology. 47:831-846.
Davenport, D.C., Martin, P.E., and Hagan, R.M. 1982. Evapotranspiration from riparian
vegetation: Water relations and irrecoverable losses for saltcedar. J. of Soil and Water Conservation. July-August:233-236.
DeLoach, C. Jack, Tracy, J.R. 1997. Effects of biological control of saltcedar (Tamarix
ramosissima) on endangered species biological assessment. USDA-ARS Grassland Soil & Water Res. Laboratory, Grassland Protection Res. Unit
DeLoach, C. Jack, and Lewis, Phil. 2000. Biology and Impact of Target Host.
http://arsserv0.tamu.edu/lewis/section2.htm. Accessed on June 5 2001. Devitt, D.A., Piorkowski, J.M., Smith, S.D., Cleverly, J.R., and Sala, A. 1997a. Plant water
relations of Tamarix spp. ramosissima in response to the imposition and alleviation of soil moisture stress. J. of Arid Environ 36:527-540.
Devitt, D.A., Sala, A., Mace, K.A., Smith, S.D. 1997b. The effect of applied water on the water
78
use of saltcedar in a desert riparian environment. J. of Hydrology. 192:233-246. Devitt, D.A., Sala, A., Smith, S.D., Cleverly, J., Shaulis, L.K., Hammett, R. 1998. Bowen ratio
estimates of Evapotranspiration for Tamarix spp. ramosissima stands on the Virgin River in southern Nevada. Water Resources Res. 34(9):2407-2414.
Dugas, W.A. and W.L. Bland. 1989. Effect of bordering soil surface moisture conditions on
evaporation from soybean. Field Crops Res. 21:161-166. Dugas, W.A., L.J. Fritschen, L.W. Gay, A.A. Held, A.D. Matthias, D.C. Reicosky, P. Steduto,
and J.L. Steiner. 1991. Bowen ratio, eddy correlation, and portable chamber measurements of sensible and latent heat flux over irrigated spring wheat. Agr. and Forest Meteorology 56:1-20.
Gatewood, J.S., Robinson, T.W., Colby, B.R., Hem, J.D., and Halpenny, L.C. 1950. Use of
water by bottom-land vegetation in Lower Safford Valley, Arizona. Geol. Survey Water-Supply Paper 1103. 216p.
Gay, L.W. and Fritchen, L.J. 1979. An energy budget analysis of water use by saltcedar. Water
Resources Res.. 15(6):1589-1592. Gay, L.W. and Sammis, T.W. 1977 Estimating phreatophyte transpiration. Proceedings of the
1977 meetings of the Arizona Section of the American Water Resources Association and the Hydrology Section of the Arizona Academy of Science held in Las Vegas, Nevada, April 15-16. Hydrology and Water Resources in Arizona and the Southwest. 7:133-139.
Glenn, E., Tanner, R., Mendez, S., Tamra, K., Moore, D., Garcia, J., and Valdes, C. 1998.
Growth rates, salt tolerance and water use characteristics of native and invasive riparian plants from the delta of the Colorado River, Mexico. J. of Arid Environ 40:281-294.
Hagemeyer, J. and Waisel, Y. 1987. An endogenous circadian rhythm of transpiration in
Tamarix spp. aphylla. Physiologia Plantarum 70:133-138. Hagemeyer, J. and Waisel, Y. 1988. Excretion of ions (Cd2+, Li+, Na+, and Cl-) by Tamarix
spp. aphylla. Physiologia Plantarum 73:541-546. Hagemeyer, J. and Waisel, Y. 1989. Influence of NaCl, Cd(NO3)2 and air humidity on
transpiration of Tamarix spp. aphylla. Physiologia Plantarum 75:280-284. Horton, J.L., Kolb, T.E., and Hart, S.C. 2001a. Leaf gas exchange characteristics differ among
Sonoran Desert riparian tree species. Tree Physiol. 21:233-241. Horton, J.L., Kolb, T.E., and Hart, S.C. 2001b. Physiological responses to groundwater depth
varies among species and with river flow regulation. Ecol. Applications, 11(4): 1046-1059.
79
Horton, J.L., Kolb, T.E., and Hart, S.C. 2001c. Response of riparian trees to interannual
variations in ground water depth in a semi-arid river basin. Plant, Cell, and Environ. 24:293-304.
Horton, J.L. and Clark, J.L. 2001. Water table decline alters growth and survival of Salix spp.
goodingii and Tamarix spp. chinensis seedlings. Forest Ecol. and Manage. 140:239-247.
Inglis, R., Deuser, C., Wagner, J. 1996. The effects of Tamarisk removal on diurnal ground
water fluctuations. Water Resources Division National Park Service Department of the Interior. Technical Report NPS/NRWRD/NRTR-96/93 36p.
Jackson, J., J.T. Ball, and M.R. Rose. 1990. Assessment of the salinity tolerance of eight
Sonoran Desert riparian trees and shrubs. USDI Bureau of Reclamation, Report, Yuma, Arizona. University of Nevada System, Desert Res. Institute, Biological Sciences Center, Reno, Nevada. 102p.
Kiniry, J.R., C.A. Jones, J.C. O'Toole, R. Blanchet, M. Cabelguenne, and D.A. Spanel. 1989.
Radiation-use efficiency in biomass accumulation prior to grain-filling for five grain-crop species. Field Crops Res. 20:51-64.
Kiniry, J.R., R. Blanchet, J.R. Williams, V. Texier, C.A. Jones, and M. Cabelguenne. 1992.
Simulating sunflower with the EPIC and ALMANAC models. Field Crops Res. 30:403-423.
Kiniry, J.R., C.R. Tischler, and G. A. van Esbroeck, 1999. Radiation use efficiency and leaf
CO2 exchange for diverse C4 grasses. Biomass and Bioenergy 17:95-112. Kiniry, J.R., Williams, J.R., Schmidt, K.M., and White, L.D. 2003. Simulating water use by
saltcedar with the Epic Model. Saltcedar and Water Resources in the West Symposium. July 16-17 San Angelo, Texas. p. 75-84.
Kleinkopf, G.E., Wallace, Arthur. 1974. Physiological basis for salt tolerance In Tamarix spp..
Plant Science Letters, 3:157-163 Kozlowski, T.T. 1997. Response of woody plants to flooding and salinity. Tree Physiol.
Monogr 1:1-29 Manrique, L.A., J.R. Kiniry, T. Hodges, and D.S. Axness. 1991. Relation between dry matter
production and radiation interception of potato. Crop Sci. 31:1044-1049. Mounsif, M., Wan, C., Sosebee, R.E. 2002. Effects of top-soil drying on saltcedar
photosynthesis and stomatal conductance. J. of Range Manage.. 55:88-93. Robinson, T.W. 1958. Phreatophytes. Geol. Survey Water-Supply Paper 1423 United States
80
Department of the Interior. 82p. Sala, Q., Smith, S.D., Devitt, D.A. 1996. Water use by Tamarix spp. ramosissima and
associated phreatophytes in a Mojave desert floodplain. Ecol. Applications 6(3): 888-898.
Shafroth, P.B., Friedman, J.M., and Ischinger, L.S. 1995. Effects of salinity on establishment
of Populus spp. fremontii (Cottonwood) and Tamarix spp. ramosissima (saltcedar) in Southwestern United States. Great Basin Naturalist 55(1):58-65.
Shafroth, P.B., Stromberg, J.C., and Patten, D.T. 2000. Woody riparian vegetation response to
different alluvial water table regimes. Western North American Naturalist 60:66-76. Smith,S.D. 1989. The ecology of saltcedar (Tamarix spp. chinesis) in Death Valley National
Monument and Lake Mead National Recreation area: An assessment of techniques and monitoring for saltcedar control in the park system. Cooperative National Park Resources Studies Unit National Park Service/University of Nevada, Las Vegas Contribution number: 041/03 65p.
Smith, S.D., Devitt, D.A., Sala, A., Cleverly, J.R., and Busch, D.E. 1998. Water Relations of
Riparian Plants From Warm Dessert Regions. Wetlands 18(4):687-696. Smith S.D. Sala, A., D.A. Devitt and J.R. Cleverly. 1995 Evapotranspiration from a saltcedar-
dominated desert floodplain: a scaling approach. In: Barrow, J.R., E.D. McArthur, E.D. Sosebee, R.E. Tausch and R.J. Comps. Proceedings: Symposium on shrubland ecosystem in a changing climate. May 1995 Las Cruces New Mexico.
Solomon, A., Beer, S., Waisel, Y., Jones, G.P., and Paleg, L.G. 1994. Effects of NaCl on the
carboxylating activity of Rubisco from Tamarix spp. jordansis in the presence and absence of proline-related compatible solutes. Physiologia Plantarum 90:198-204.
Stevens, L.E. 1989. Mechanisms of riparian plant community organization and succession in
the Grand Canyon, Arizona. Dissertation. Northern Arizona University. Stromberg, J. 1998. Dynamics of Fremont cottonwood (Populus spp. fremontii) and saltcedar
(Tamarix spp. chinensis) populations along the San Pedro River, Arizona. J. of Arid Environ (19980 40:133-155.
Tesky, Julie L. 1992. Distribution and Occurrence Species: Tamarix spp. ramosissima.
http://www.fs.fed.us/database/feis/plants/shrub/tamram/all.html Accessed on June 2001.
Tomanek, G.W. and R.L. Ziegler. 1962. Ecological studies of salt cedar. Division of Biological
Sciences, Fort Hayes State College, Hays, Kansas. 128p. Tomar, O.S., Minhas, P.S., Sharma, V.K., Singh, Y.P., and Gupta, Raj K. 2003. Performance
81
of 31 tree species and soil conditions in a plantation established with saline irrigation. Forest Ecol. and Manage. 177:333-346.
Vandersale, M. W., Glenn, E.P., and Walworth, J.L. 2001. Tolerance of five riparian plants
from the lower Colorado River to salinity, drought and inundation. J. of Arid Environ 49:147-159.
Van Hylckama, T.E.A. 1963. Growth, development and water use by saltcedar (Tamarix spp.
pentandra) under different conditions of weather and access to water. Presented at the General Assembly 1963 of the International Association of Scientific Hydrology in Berkeley, California. 20p.
Van Hylckama, T.E.A. 1970. Water use by salt cedar. Water Resources Res.. 6(3):728-735. Weeks, E.P., Weaver, H.L., Campbell, G.S., and Tanner, B.D. 1987. Water use by saltcedar
and by replacement vegetation in the Pecos river floodplain between Acme and Artesia, New Mexico. Studies of Evapotranspiration U.S. Geol. Survey Professional Paper 491-G. 37p.
Wilkinson, R.E. Water stress in salt cedar. 1972. Botanical Gazette 133(1):73-77. Williams, M.E., and Anderson, J.E. 1977 Diurnal trends in water status, transpiration and
photosynthesis. Hydrology and Water Resources in Arizona and the Southwest. 7:119-124.
White, L.D., Hays, K.B., and Schmidt, K.M. 2003. Water use by saltcedar and associated
vegetation along selected rivers in Texas. Saltcedar and Water Resources in the West Symposium. July 16-17 San Angelo, Texas. p. 53-73.
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APENDIX A
Table 19. Summary of evapotranspiration studies on saltcedar.
Study Author Method Site description
Depth to water table in m cm of use2
Anderson 1977 Gas exchange chamber
Benardo, New Mexico
1.5 gH2O dm-2 h-
1 Cleverly et al 2002 Eddy Covariance Non-flooding 74Cleverly et al 2002 Eddy Covariance Non-flooding 76
Cleverly et al 2002 Eddy Covariance
Unflooded mixture of plants 84.8
Cleverly et al 2002 Eddy Covariance Flooding 111.0Cleverly et al 2002 Eddy Covariance Flooding 122.0
Cleverly et al 2002 Eddy Covariance
Flooded monospecific stand of saltcedar 139.9
Davenport et al 1982 Lysimeter 1.5 72.0Davenport et al 1982 Drums 3905 plants/ha 39.7Davenport et al 1982 Drums
15618 plants/ha 116.1
Davenport et al 1982 Drums
27768 plants/ha 173.9
Davenport et al 1982 Drums
62474 plants/ha 284.5
Davenport et al 1982 Drums Isolated plant 5.8 kg H2O/day Davenport et al 1982 Drums Isolated plant 5.6 kg H2O/day Davenport et al 1982 Drums Isolated plant 5.7 kg H2O/day Devitt et al 1998 Bowen Ratio 11% advection 75.0
Devitt et al 1998 Bowen Ratio
25% canopy dieback caused increase in 145.0
2 When yearly water use was not given water use was assumed to have a 180-day growing season and converted when possible.
83
advection to 65%
Gatewood et al 1950 Well
Baccharis and saltcedar 1.1 125.81467
Gatewood et al 1950 Lysimeter 1.2 266.7Gatewood et al 1950 Lysimeter 1.2 276.9Gatewood et al 1950 Lysimeter 1.3 297.2Gatewood et al 1950 Well 1.4 137.5Gatewood et al 1950 Lysimeter 1.7 244.0Gatewood et al 1950 Well 1.8 199.6Gatewood et al 1950 Well 1.9 156.5Gatewood et al 1950 Lysimeter 1.8 299.7Gatewood et al 1950 Lysimeter 1.8 223.5Gatewood et al 1950 Lysimeter 1.8 243.8Gatewood et al 1950 Lysimeter 1.9 241.3Gatewood et al 1950 Well 1.9 109.0Gatewood et al 1950 Lysimeter 2.0 233.7Gatewood et al 1950 Lysimeter 2.1 215.9Gatewood et al 1950 Well 2.17932 274.5Gatewood et al 1950 Well 2.2 155.4Gatewood et al 1950 Well 2.4 92.2Gay and Sammis 1977 Energy balance 0.5-2.8 µg/cm2-s Gay and Sammis 1977 Lysimeter Lysimeter 1.5 143.8Gay and Sammis 1977 Bowen Ratio Bowen ratio 147.6Glenn et al 1998 Green house 12.86 g g-1 day-1
Ingles et al 1996 Well Tamarix spp. 0.8 186.5
84
thicket Kiniry et al 2003 Model simulation Pecos River 37.7Kiniry et al 2003 Model simulation Pecos River 68.8Kiniry et al 2003 Model simulation Colorado River 106.0Kiniry et al 2003 Model simulation Pecos River 128.6Kiniry et al 2003 Model simulation Canadian River 140.4Kiniry et al 2003 Model simulation Pecos River 188.9Kiniry et al 2003 Model simulation Pecos River 220.3Kiniry et al 2003 Model simulation Pecos River 226.0Robinson 1958 Tanks Tamarix spp. 1.4 142.6Robinson 1958 Tanks Tamarix spp. 1.7 167.0Robinson 1958 Well 1.8 183.8Robinson 1958 Tanks Tamarix spp. 2.1 213.4Robinson 1958 Tanks Tamarix spp. 2.2 223.4Robinson 1958 Tanks Tamarix spp. 2.4 236.2Robinson 1958 Tanks Tamarix spp. 2.6 256.6Robinson 1958 Tanks Tamarix spp. 2.8 279.5Tomanek, G.W., Ziegler, R.L. (1962) Field box apparatus
Weeks et al 1987 Eddy Covariance Burned 1.8 34.2Weeks et al 1987 Eddy Covariance Burned 1.8 50.4Weeks et al 1987 Energy budget Burned 1.8 57.6Weeks et al 1987 Energy budget Burned 1.8 73.8Weeks et al 1987 Eddy Covariance Mowed 3.3 25.2Weeks et al 1987 Eddy Covariance Mowed 3.3 32.4Weeks et al 1987 Eddy Covariance Mowed 3.3 39.6Weeks et al 1987 Eddy Covariance Mowed 3.3 39.6Weeks et al 1987 Eddy Covariance Mowed 3.3 46.8Weeks et al 1987 Eddy Covariance Mowed 3.3 63Weeks et al 1987 Energy budget Mowed 3.3 37.8Weeks et al 1987 Energy budget Mowed 3.3 77.4Weeks et al 1987 Energy budget Mowed 3.3 79.2Weeks et al 1987 Energy budget Mowed 3.3 86.4Weeks et al 1987 Energy budget Mowed 3.3 108.0Weeks et al 1987 Eddy Covariance Old growth 3.4 12.6Weeks et al 1987 Eddy Covariance Old growth 3.4 21.6Weeks et al 1987 Eddy Covariance Old growth 3.4 21.6Weeks et al 1987 Eddy Covariance Old growth 3.4 23.4Weeks et al 1987 Eddy Covariance Old growth 3.4 28.8Weeks et al 1987 Eddy Covariance Old growth 3.4 55.8Weeks et al 1987 Eddy Covariance Old growth 3.4 73.8Weeks et al 1987 Energy budget Old growth 3.4 23.4Weeks et al 1987 Energy budget Old growth 3.4 32.4Weeks et al 1987 Energy budget Old growth 3.4 34.2Weeks et al 1987 Energy budget Old growth 3.4 48.6
86
Weeks et al 1987 Energy budget Old growth 3.4 50.4Weeks et al 1987 Energy budget Old growth 3.4 84.6Weeks et al 1987 Energy budget Old growth 3.4 86.4
White et al 2003 Well
Canadian River mixed growth well 3 0.4572 351.4344
White et al 2003 Well
Canadian River mixed growth well 4 0.4572 421.2336
White et al 2003 Well
Colorado river mono-typic stand of saltcedar 6.096 17.6784
White et al 2003 Well
Colorado river mono-typic stand of saltcedar 6.096 32.004
White et al 2003 Well
Colorado river mono-typic stand of saltcedar 6.096 81.9912
White et al 2003 Well
Colorado river mono-typic stand of saltcedar 6.096 84.4296
White et al 2003 Well
Pecos river mono-typic stand of saltcedar 120.396
White et al 2003 Well
Pecos river mono-typic stand of saltcedar 288.6456
Permanent Address 5670 Wegner Rd New Braunfels, TX 78132
Education Texas A&M University, College Station, Texas Bachelor of Science in Rangeland Ecology and Management (May 2001) Master of Science in Rangeland Ecology and Management (December 2003)